Broadband cable telephony network architecture IP ITN network architecture reference model

ABSTRACT

The present invention provides a system and method for a reliable, low-cost, secure Internet Protocol (IP) based network that provides broadband-based voice communications as well as video and data communications. The IP network is arranged to function with the infrastructure of the Public Switched Telephone Network (PSTN), to control telephone calls in SS 7  type networks and to provide the features, applications, and services of the typical SS 7  networks in a voice over IP network. The present invention supports large effective call volumes, allows accommodation of a wide range of broadband-based service platforms, provides flexibility to support current and future calling feature services, and provides high quality voice transmission.

A cross-reference of related applications are provided at the end of the Detailed Description of Preferred Embodiments section of the present application.

FIELD OF THE INVENTION

The present invention relates to communication between users in diverse communication systems, and more particularly, to providing a broadband communication system including an Internet Protocol-based Network, a cable-based access network, other high-speed networks and a public switched telephone network.

BACKGROUND OF THE INVENTION

Present day telephony voice networks have a network built around circuit switches, end offices, a toll network, tandem switches, and twisted pair wires. These voice networks are referred to as a public switched telephone network (PSTN) or plain old telephone service (POTS). Due to bandwidth limitations of plain old telephone service (POTS), there is an inherent inability to efficiently integrate multiple types of broadband services such as IP telephony, high-speed data communication for personal computers (PC), and video on demand (VOD), Interactive television (ITV) and cable TV (CATV) services. Accordingly, a new broadband architecture is required for data-optimized access networks with reliable quality that can share voice, data and video communications efficiently and at low cost, allowing businesses to connect directly to data networks, thus changing the profile of the voice network while optimizing broadband service-based data transmission based on packet and cell technologies.

SUMMARY OF THE INVENTION

Aspects of the invention include providing broadband access capabilities or enhanced services for use in conjunction with a packetized network such as an Internet Protocol (IP) based system infrastructure.

Other aspects of the invention include providing one or more of the following either individually, or in any combination or subcombination: a new broadband architecture; broadband network capabilities, including local access; enhanced services for use in conjunction with a packetized network such as an Internet Protocol (IP) based system infrastructure.

The present invention includes a powerful, facilities-based, end-to-end Internet Protocol (IP) based network infrastructure that provides voice, data and video communication service with reliable security to users at a minimum cost. A plurality of networks converge to IP as a protocol of choice in wide area networking, providing the network with a protocol consistency that facilitates deployment of new broadband services. In the present invention, the IP network may be arranged to interwork with the infrastructure of the Public Switched Telephone Network (PSTN), which is built around traditional SS7 networks. The present invention may control telephone calls in SS7 type networks and provide the features, applications, and services of the typical SS7 networks in the new voice over IP network.

Thus, the present invention provides voice over IP network that is reliable, may be fully interoperable with PSTN including SS7, may support much larger low cost call volumes than the present network systems, may allow accommodation of a wide range of service platforms including the flexibility to support current and future calling features, and typically provides low cost and high quality voice transmission.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic representation of a broadband network (e.g., broadband IP based network) in accordance with a preferred embodiment of aspects of the present invention.

FIG. 2 shows a block diagram of a preferred embodiment of a centralized control (IP central station) in accordance with aspects of the present invention.

FIG. 3 shows a block diagram of a preferred embodiment of a local control apparatus (broadband residential gateway) in accordance with aspects of the present invention.

FIG. 4 shows a detailed schematic representation of an exemplary embodiment of the broadband network shown in FIG. 1.

FIG. 5 is a signal flow diagram illustrating a typical on-network to off-network call according to one preferred method of operating the broadband network shown in FIG. 1.

FIG. 6 is a signal flow diagram illustrating a typical on-network to on-network call according to one preferred method of operating the broadband network shown in FIG. 1.

FIG. 7 is a schematic representation of one embodiment of a Customer Premises Apparatus coupled to an Internet Protocol Capable/Hybrid Fiber Coaxial (HFC) network in accordance with the present invention.

FIG. 8 shows a schematic of one embodiment of a HFC distribution network for connecting a Head-end Hub with the CPE network in accordance with the present invention.

FIG. 9 shows a one embodiment of a spectrum use diagram for the coaxial portion of an HFC network in accordance with the present invention.

FIG. 10 is a schematic representation of one embodiment of a HEH architecture in accordance with the present invention.

FIG. 11 is a schematic representation of one embodiment of a packet over SONET High-speed Packet Network in accordance with the present invention.

FIG. 12 is a schematic representation of one embodiment of the connectivity between the VG and the PSTN network in accordance with the present invention.

FIG. 13 is a schematic representation of one embodiment of a VG that is router-based with Voice Feature Card and DSP Module cards to do the voice processing in accordance with the present invention.

FIG. 14 shows a schematic representation for one embodiment of an architecture for a Secured Management Data Network (SMD net) interconnect system in accordance with the present invention.

FIG. 15 is a block diagram of one embodiment of a Broadband Residential Gateway in accordance with the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention provides a system and method for a reliable, low-cost, secure Internet Protocol (IP) based network that provides broadband-based voice communications as well as video and data communications that function together with the infrastructure of the Public Switched Telephone Network (PSTN) to control telephone calls in SS7 type networks and to provide the features, applications, and services of the typical SS7 networks in a voice over IP network. In particular, the present invention supports much larger low-cost call volumes than the present network systems, allows accommodation of a wide range of broadband-based service platforms, provides flexibility to support current and future calling feature services, and provides high quality voice transmission.

A new system is provided for broadband access and applications. Unless otherwise indicated by the appended claims, the present invention is not limited to the preferred embodiments described in this section but is applicable to other integrated multimedia communication systems.

I. INTEGRATED COMMUNICATION SYSTEM OVERVIEW

Referring to FIG. 1, an exemplary embodiment of a broadband network 1. The broadband network generally provides interconnection between a plurality of customer locations utilizing various interconnection architectures including Internet Protocol (IP) based network, various existing systems (legacy systems) such as the public switched telephone network (PSTN), ATM networks, the Internet, signaling networks, as well as other systems. The broadband network provides versatile intelligent conduits that may carry, for example, Internet Protocol (IP) telephony or multimedia signals between the customer premises over, for example, the public switched telephone network, Internet, or wireless communication networks.

Again referring to FIG. 1, the broadband network 1 may include one or more customer premises equipment (CPE) units 102. The customer premise equipment 102 may be variously configured. In one example, the customer premise equipment 102 may include one or more local control devices such as a broadband residential gateway (BRG) 300. Although the broadband residential gateway is preferably disposed in a residence for many aspects of the invention, in exemplary embodiments, it may also be disposed in a business or other location. The broadband residential gateway 300 may be variously configured to provide one or more integrated communication interfaces to other devices within the customer premise equipment 102 such as televisions (TV), personal computers (PC), plain old telephone system (POTS) phone(s), video phones, IP enabled phones, and other devices. For example, the broadband residential gateway 300 may provide one or more telephone port connections (e.g., plain old telephone system), Ethernet connections, coaxial connections, fiber distributed data interface (FDDI) connections, wireless local area network (LAN) connections, firewire connections, and/or other connections to a plurality of devices such as plain old telephones, IP based phones, television converters, e.g., cable television (CATV) set top devices, televisions, digital televisions, high definition televisions (HDTV), video phones, and other devices. In exemplary embodiments, the broadband residential gateway 300 may support communications between any of the aforementioned devices in intra-premises calling and/or extra-premises calling. Further, when the broadband residential gateway 300 is used in a business environment, it can function as a private branch exchange or key type telephone system.

In FIG. 1, broadband residential gateway 300 is illustrated as a single physical device. This configuration is appropriate where centralization of maintenance and control is desirable. Alternatively, the broadband residential gateway 300 may be separated into more than one physical device allowing functionality to be distributed to a plurality of different physical locations in the customer premise and/or broadband network 1. However, in many embodiments, having a centralized broadband residential gateway 300 located in a single location provides ease of maintenance, control, and re-configuration as well as a reduction in cost due to shared functionality. For example, the broadband residential gateway may be configured to provide the intelligence needed to allow each of the customer premises equipment devices to operate within the broadband network 1. For example, analog voice may be converted to digital data and packetized for transmission in an appropriate output protocol such as an Internet protocol (IP).

In exemplary embodiments, the broadband residential gateway 300 may function to couple devices within the customer premise equipment 102 to the rest of the broadband network 1 using any suitable broadband communication mechanism. In the embodiment shown in FIG. 1, the broadband residential gateway 300 utilizes a hybrid fiber-coaxial plant 112 to couple the broadband residential gateway 300 to the rest of the broadband network 1. The hybrid fiber-coaxial plant 112 may be preferred in many embodiments over other broadband communication mechanisms because of the large number of homes currently connected to cable networks, the capacity for shared access, and the ability for asymmetric data access speeds which allow high quantities of data to be distributed to the various devices in the customer premises equipment 112. The hybrid fiber-coaxial plant 112 may include coaxial cable and/or optical fiber networks in any suitable combination. The hybrid fiber-coaxial plant 112 may provide an intelligent broadband conduit between the broadband residential gateway 300 and a gateway such as the head-end hub (HEH) 115. The head-end hub 115 may be variously configured to provide various services and/or interconnections with the rest of the broadband network 1. For example, the head-end hub 115 may provide an interconnection point to gather and aggregate external services (e.g., off air and satellite video, public switched telephone network voice, multimedia messages, and Internet data) for distribution to and from the hybrid fiber-coaxial plant 112. With respect to telephony and multimedia calls, the head-end hub 115 may function as intelligent conduit for connection and communication between the hybrid fiber-coaxial plant 112 and external networks such as an IP network 120 and/or an ATM/frame relay/cell relay network 185.

The broadband network 1 may include any number of interconnected head-end hubs 115, IP networks 120, and/or ATM networks 185. Further, the IP network 120 and/or ATM network 185 may be connected to one or more other networks and devices such as:

-   -   (1) external networks including a public switched telephone         network (PSTN) 170, an signaling system 7 (SS7) network 170, an         Internet 180, and/or a wireless network 144;     -   (2) various components including one or more private branch         exchanges 146, terminals 142 including computers and wireless         devices, and/or one or more stand alone broadband residential         gateway 300;     -   (3) one or more administration centers 155;     -   (4) one or more secure network management data networks 190 such         as a network operations center (NOC);     -   (5) one or more billing systems 195 such as OSS; and/or     -   (6) one or more centralized control centers such as what is         referred to as an IP central station 200.

The IP network 120 and/or ATM network 185 may include one or more routers and/or other devices to route, for example, telephony calls, multimedia calls, signaling messages, administrative messages, programming messages and/or computer data between the various devices in the broadband network 1 such as the head-end hub 115, the public switched telephone network 160, the private branch exchange (PBX) 146, as well as the other devices discussed above. In preferred embodiments, the information traveling in the IP network 120 may be packetized and formatted in accordance with one of the Internet protocols. The IP network 120 may also include gateways to interface with the various other networks and/or devices. For example, the gateways may be distributed at the edge of the IP network where the IP network interfaces with one of the other devices or networks. Alternatively, the gateways interfacing the IP central station 200 to, for example, the Internet 180, public switched telephone network (PSTN) 160, signaling system 7 (SS7) 170, wireless networks 144, ATM/frame/cell relay networks 185 may be provided in the IP central station 200, or in both the IP network 120 and the IP central station 200, and/or partially distributed between the IP network 120 and the IP central station 200. Where the gateways are separated by an IP network 200, an appropriate transport protocol may be utilized to logically connect the IP central station 200 to the particular gateway.

The IP central station(s) 200 may be connected to, for example, one or more IP networks 120, ATM networks 185, secure management data networks 190, and/or administration centers 155. The IP central station 200 may be variously configured to include one or more servers and/or one or more gateways. In exemplary embodiments, the servers and gateways provide the necessary intelligence and traffic management capabilities to enable information, e.g., IP telephony signals, to travel through the broadband network 1. For example, the IP central station 200 may be configured to manage voice information transfer from the public switched telephone network 160, through the IP network 120, and into and out of one or more devices such as those connected to a broadband residential gateway 300. The IP central station may be configured to store various control and system information such as location, address, and/or configurations of one or more broadband residential gateways 300, as well as other routing and call set-up information.

In exemplary embodiments, one or more administration centers 155 may be connected to the IP network 120 and provide billing and local directory number portability administration. The local number portability may be handled by one or more Local Service Management System (LSMS) which may be included in the administration center 155 and/or in the IP central station 200. Further, the Secure Management Data Network 190 may also include a mechanism for transferring various information such as billing, call tracking, and/or customer service provisioning. Various existing systems may be utilized to provide this information such as existing billing systems (OSS) 195 and/or one or more network operations center (NOC). The network operations centers may be included in the administration center 155, the IP central station 200, and/or the billing system 195. The network operations center (NOC) may be variously configured to include a translation server to allow communications with the various disparate entities (e.g., legacy systems) in the broadband network 1.

The IP network 120 and/or the ATM network 185 illustrated in FIG. I may include one or a plurality of sub-networks. Each of the sub-networks may include its own IP central station 200 in a distributed configuration, with certain routing data replicated across all IP central stations or each sub-network may be connected to a single centralized IP central station 200. Where the IP network 120 includes one or more sub-networks, each sub-network may be connected to multiple head-end hubs 115. Further, each head-end hub 115 may be connected to multiple hybrid fiber-coaxial plants 112, and each hybrid fiber-coaxial plant 112 may be connected to multiple pieces of customer premises equipment 102 and/or broadband residential gateways 300. The IP network 120 provides an interconnected broadband network which may be utilized to transport and route packetized information to and from diverse geographic locations and may be used on a national or international basis. Further, the IP network 120 and/or ATM network 185 may utilize private network facilities and/or may be provisioned over a shared network such as the Internet.

The IP central station 200 may be configured to provide connectivity for the broadband residential gateway 300 to the Internet 180 (e.g., World Wide Web (www)), as well as connectivity to other external networks such as public switched telephone network 160 and signaling system 7 (SS7) 170 for end-to-end voice, multimedia, and data applications, for example voice over IP telephony. IP packets traveling through the IP network provide for priority so that, for example, voice packets are given priority over data packets to maintain certain VoIP telephony QoS requirements and a leased line concept for packet traffic which may have an even higher priority. However, the system is sufficiently flexible so that the priority can be dynamically altered according to customer preferences, variable billing rates, traffic patterns, and/or congestion.

A. INTERNET PROTOCOL CENTRAL STATION

Referring to FIG. 2, the IP central station 200 may be variously configured. In preferred embodiments, it may be configured to ensure seamless integration of IP based communication system including the IP network 120 with the public switched telephone network 160, signaling system 7 (SS7) network 170, and the Internet 180 so that packetized data, for example, voice calls and information data, is properly transferred between the broadband residential gateway 300, the public switched telephone network 160 and/or the Internet 180. In one embodiment, the hybrid fiber-coaxial plant 112, head-end hub 115, and IP network 120, provide a virtual signaling conduit for packetized voice and data which may, with the coordination of the IP central station 200, be provided in the appropriate format between the broadband residential gateway 300 and the public switched telephone network 160 and/or Internet 180.

Again referring now to FIG. 2, the IP central station 200 may include a central router 200, for example, a gigabit switch, which may be utilized to interconnect various servers and gateways contained in the IP central station 200. The central router 210 provides for example Ethernet switching and aggregate traffic between servers, gateways and the IP network 120 and/or ATM network 185 backbone. In one exemplary embodiment, the central router 210 provides high-speed, non-blocking IP and IP multicast Layer 3 switching and routing. The IP central station 200 may include one or more of the following servers: the least cost server (LCS) 255, the time of day (TOD) server 212, the dynamic host control protocol (DHCP) server, the trivial file transfer protocol (TFTP) server, and the domain name service (DNS) server 214, the system management (SM) server 216, the call manager (CM) server 218, the announcement server (AS) 220, the multimedia server (MS) 222, and/or the conference server (CS) 224. As illustrated in FIG. 2, the servers may be separate servers, for example the call manager server 218, or may be incorporated into a single server. In the exemplary embodiment, the dynamic host control protocol server 131, trivial file transfer protocol server 132, and the domain name service server 214 are each incorporated in a single server facility. Each server in the IP central station 200 may include computer(s), storage device(s), and specialized software for implementing particular predefined functions associated with each server. In this manner, the servers in the IP central station may be provisioned as a main server and one or more back-up servers to provide redundant processing capabilities. Similarly, the router may be implemented as a main router and a back-up router with similar routing functionality.

The IP central station 200 may also include, for example, one or more of the following gateways: a element management gateway (EMG) 238, an accounting gateway (AG) 240, an Internet (Boarder) gateway (IG) 236, a signaling system 7 (SS7)) gateway (SG) 234, a voice gateway (VG) 232, and/or a multimedia gateway (MG) 230. The IP central station 200 may utilize one or more of these gateways to provide centralized system intelligence and control of voice and/or data IP packets.

In exemplary embodiments, the dynamic host control protocol server and domain name service server 214 may operate to dynamically assign IP addresses devices in the customer premise equipment 102. Where a dynamic IP assignment scheme is used, the customer premises equipment may be provided with one or a plurality of dynamic IP assignment when activated initially, and/or at the initiation of each active secession. Where an IP address is assigned when the device is initially activated, it may be desirable to assign a single IP address to a single broadband residential gateway and assign a port address to devices connected to the broadband residential gateway 300. In other embodiments, an individual IP address may be assigned to each device coupled to the broadband residential gateway 300. For example, the broadband residential gateway may include and/or be coupled to one or more cable modems, IP phones, plain old telephone system phones, computers, wireless devices, CATV converters, video phones, and/or other devices which each may be assigned a unique static and/or dynamic IP address and/or a port of a one of these IP addresses. The particular protocol for allocating IP addresses and/or ports may be specified using protocols defined in the dynamic host control protocol server 214. In exemplary embodiments, the dynamic host control protocol and DN server 214 may be configured to assign available IP addresses from address pools based, for example, on the identity or type of requesting device, the amount of use expected for the requesting device, and/or predefined assignment protocols defined in the dynamic host control protocol and DN server 214. In centralized embodiments, it may be desirable to configure the call manager (CM) 218 to provide sufficient information such that the domain name service server 214 can distinguish between static IP devices, dynamic IP devices, registered devices, unregistered devices, and registered devices that have been assigned to a particular class of service e.g., data vs. telephony, un-provisioned, vs. provisioned, etc.

The trivial file transfer protocol (TFTP) server 214 may be configured to transfer certain information to/from one or more broadband residential gateways 300. In exemplary embodiments, the trivial file transfer protocol server provides Data Over Cable Service Interface Specifications (DOCSIS) configuration information containing QoS parameters and other information required for the broadband residential gateway 300 to operate optimally.

The time-of-day (TOD) server 212 may include a suitable facility for maintaining a real time clock such as an RFC868-compliant time server. In exemplary embodiments, the time-of-day server 212 provides system messages and/or responses to system inquiries containing a coordinated time, e.g., universal coordinated time (UCT). The universal coordinated time may be used by any of the servers and/or devices in the broadband network 1. For example, the broadband residential gateway 300 may use the universal coordinated time to calculate the local time for time-stamping error logs.

The system management (SM) server 216 may include responsibility for the overall operational state and functioning of components the broadband network 1, either alone, or in combination with other system management servers 216. The system management (SM) server 216 may be variously configured to provide monitoring and administrative functions for devices within the broadband network 1. For example, the system management server 216 may be configured to provide management of various database functions, memory buffer functions, and software utility functions within the broadband network 1. Software management includes, for example, version control, generic control, and/or module control.

The least cost server (LCS) 255 may be variously configured to enable the system to determine the least cost routing of telephone and data transmission throughout the network. The least cost server 255 may also provide one or more broadband residential gateway users capability to select between, for example, cost and Quality of Service (QoS).

The announcement service (AS) server 220 may be variously configured. In exemplary embodiments, it may store and send announcements to specified destinations and/or all destinations based on instructions received by, for example, the call manager (CM) server 218. The announcement server 220 receives, for example, Media Gateway Control Protocol (MGCP) or later signaling (e.g., H.GCP—an ITU standard Gateway Control Protocol) control messages from the call manager 218, and sends announcements to one or more voice gateways (VG) 232 and/or the one or more broadband residential gateway 300 (e.g., using Real Time Protocol (RTP) packets). The announcement server 220 may send an announcement once, a predetermined number of times, or in a continuous loop. The announcement server 220 may detect when a phone or other device has been taken off-hook and play an advertisement or other announcement to the user. Where a user has signed-up for an advertising plan whereby phone rates are reduced in return for advertising revenue generated by the advertisements, the announcement server 220 may be utilized to track the number of individuals with a particular income, age, or other profile which hear the advertisement. The announcement server 220 may respond to requests from individual system devices such as one of the broadband residential gateways 300 and/or under control of, for example, the call manager 218. Where the announcement server is under control of the call manager 218, the call manager may be configured to control various operating parameters of the announcement server. For example, the call manager 218 may request that certain announcements are sent once, a specified number of times, or in a continuous loop.

In still further embodiments, announcements may be generated elsewhere in the broadband network 1, stored as files, and distributed to one or more announcement servers via a file transfer protocol or resource such as the trivial file server 214 using one or more file transfer protocols. In many embodiments, it is desirable to store announcements in an appropriate encoding format (e.g., G.711 or G.729) within the Announcement Server. The announcement may have an audio component and/or a audio/video component. The audio/video component may be stored using a combination of an encoding format (e.g., G.711) and/or a standard file format such as wave (WAV), MPEG, and other suitable formats.

In one exemplary method of operation, a user picks up a telephone which sends a signal to the call manager 218. Subsequently, the call manager 218 may establish a connection to the announcement server 220 and play one or more pre-recorded and/or predetermined announcement (hypertext and/or audio). Signaling tones such as a busy signal may be played by the broadband residential gateway 300 or the call manager 218, but Special Information Tones (SIT) and/or messages may also be included as part of an announcement file. In this way, the user experience is enhanced such that the user receives a busy message and/or hypertext announcement providing one of several options for contacting the called party. The announcement server 220 may have information entered by a user using, for example, a broadband residential gateway to provide additional information to the called party. The additional information may include the ability to leave a message, type-in a chat note, page the called party, barge-in on the call, and/or other user or system defined call handling capabilities.

The announcement server 220 may also be programmed with various system messages such as an announcement indicating that a number dialed is incorrect or that the call did not go through as dialed, that the lines are busy, that all lines between two countries are currently busy, that the called party has changed numbers, that the called parties phone has been disconnected, that one or more system errors have occurred, and/or other announcement messages.

The call manager (CM) 218 may be variously configured. In exemplary embodiments, the call manager 218 provides a centralized call control center for supporting call set-up and tear-down in the broadband network 1. The call manager 218 may be configured to include trunk and line information maintenance, call state maintenance for the duration of a call, and/or user service features execution. The call manager 218 may also provide for call processing functions such as a standardized call model for processing the various voice connections such as voice over IP calls. In exemplary embodiments, a standardized “open” call model may be utilized which supports standardized application programming interfaces (APIs) to provide transport services and other user functions such as calling cards. An open application programming interface and call set-up interface in the call manager will enable third party applications to be loaded into the call manager 218 and broadband residential gateway 300. This will facilitate the development of third party applications for enhancing the functionality of components in the broadband network 1. For example, third parties and other equipment vendors may manufacture various broadband residential gateways 300 for use in the broadband network 1 by writing applications to support the open call model of the call manager 218. The call manager 218 and/or broadband residential gateway 300 may also be configured to execute and/or accept commands form a standardized scripting language which may generate instructions for the call manager 218 and/or broadband residential gateway 300 to execute various functions. The scripting functionality may include the ability to execute an entire call model including interfaces to the signaling system 7 (SS7) 170, public switched telephone network 160, IP network 120, ATM/frame/cell relay network 185, and/or other functions within, for example, IP central station 200 such as the multimedia server 222, announcement server 220, system management server 216, conference server 224, time of day server 212, least cost server 255, and/or domain name server 214.

The call manager 218 may also be configured to maintain the call states for each call it handles (e.g., a voice over IP call) and respond to system events created by, for example, the multimedia gateway control protocol (MGCP) messages and/or integrated services digital network user part (ISUP) messages for signaling system 7 (SS7) protocol that may occur during the processing of a call. Exemplary events handled by the call manager 218 include call state changes, call feature changes/call feature triggering events, changes in the status of lines and trunks, and/or error conditions. Further, the call manager 218 may interact with devices connected to a single circuit on the public switched telephone network 160 and/or a device connected to a port of the broadband residential gateway 300. In this manner, new devices may be added to the infrastructure and operate using the open call model contained in the call manager 218.

The call manager 218 may also include storage for subscriber and network configuration, a cache server for faster access to frequently used data, a routing engine for selecting an appropriate routing algorithm (e.g., least cost routing), and/or a service broker which provides the data and logic for specific services. In addition, the call manager 218 may include an authentication (AC) server 245 that provides authentication of various devices, objects, packets and users in the integrated multimedia system. In this manner, a user may verify the identity of the calling or called party.

The call manager 218 may interact with the signaling gateway (SG) 234, the accounting gateway (AG) 240, the element management gateway (EMG) 238, the voice gateway (VG) 232, and the multimedia gateway (MG) 230 using any suitable protocol such as IP and an interconnection mechanism such as the central router 210. In one preferred embodiment, the call manager 218 may be configured to utilize signaling messages such as: a) ISUP messages over Common Object Broker Architecture (COBRA) interface to and/or from signaling gateway 234, b) MGCP, SIP—simple internet protocol, H.GCP, and/or other suitable control messages to and/or from the announcement server 220, c) call event records in modified Radius format to the accounting gateway 240, d) Radius (or Enhanced Radius or compatible protocol) control messages to and/or from the voice gateway 232 and/or the broadband residential gateways 300, and e) signaling network management protocol (SNMP) messages to and/or from the element management gateway 238.

The call manager 218 may incorporate one or more databases. For example, the call manager 218 may include database information such as (1) a resources database that provides an identification of what resources are connected to the broadband network 1 and their current state; (2) a trunk/gateway database that indicates which gateway serves what circuits in a trunk; (3) a customer database which indicates whether a call is authorized, identifies what services a line supports and determines whether a telephone number is on or off the integrated IP communication network; (4) a numbering plan/least cost routing database which provides routing information that enables the IP central station 200 to choose the correct trunk as a function of the call number; and (5) a local number portability (LNP) database that indicates the North American Numbering Plan (NANP) and associated prefixes which are open for association with the number portability service; and (6) an address of the service control point (SCP) towards which requests for translating these local portability numbers should be routed.

In exemplary embodiments, the broadband network 1 includes equipment compatible with the COBRA standard. COBRA may be utilized to allow applications from a plurality of vendors to operate with each other. The COBRA standard allows a company, such as AT&T, to build its network using multi-vendor equipment and yet ensure seamless integration and operation. Some of the major areas covered by COBRA v. 2.2 include: Inter-ORB Bridge Support, General Inter-ORB Protocol (GIOP) support, Internet Inter-ORB Protocol (IIOP) support, and Environment Specific Inter-ORB Protocol (ESIOP) support. The call manager 218 may integrate these protocols to facilitate call set-up with diverse equipment. This is advantageous in that equipment from a plurality of vendors may interoperate over the broadband network 1 without modification.

The multimedia server (MS) 222 may be variously configured. For example, one or more multimedia servers may provide support for multimedia messaging service and/or the overall management of multimedia voice and mail messages transmitted across the broadband network 1. The multimedia server may be configured to support e-mail (e.g., html) messages, voice mail (audio) messages, and/or video mail (audio and video) messages. The multimedia messages may include standard pre-configured system messages, advertising messages, and/or user defined messages. In either event, where the messages are stored in a centralized location, the multimedia server may provide such storage. Where the multimedia server 222 provides storage for the multimedia messages, a database may be utilized for indexing, storage, and retrieval of such messages. In exemplary systems, the user may access predetermined ones of these messages. The multimedia server 222 may utilize IP as a method of communicating with other devices across the broadband network 1.

The conference server (CS) 224 may be configured to provide for multiparty conference calls using, for example, IP voice packets during an IP telephony or multimedia session call. The conference server 224 may include specialized software that runs on a computing platform having associated multiplexing and demultiplexing capability for segregating and aggregating user information packets. For example, the conference server may log several calls into a conference session. When information packets are sent from one or more phones, they are aggregated and sent to the other phones on the conference call. The conference server 224 may use any suitable communication protocol such as H.GCP or SIP. The conference server 224 may function to aggregate user information from two or more users onto a single call path. The conference server 224 may include one or more “call-in numbers” and be controlled from any location, e.g., a centralized operator location and/or one or more broadband residential gateways 300. It may be desirable to have the conference server 224 configured such that some callers simply monitor the call without voice interruption while other callers have both voice transmit and receive capabilities. Where a caller is not given the privileges associated with active participation in the call, voice packets from these users are discarded. For example, a CEO may have a conference call with a plurality of financial advisors and invite the press to listen on the call without interruption capabilities.

The gateways in the IP central station 200 may be configured to provide translation of signals to and/or from the various servers in the IP central station 200, the IP network 120, the public switched telephone network 160, the signaling system 7 (SS7) network 170, the Internet 180, and/or the secured management data (SMD) network 190. The gateways typically support one or more of the following group of functions: call processing; signaling system 7 (SS7) connectivity; billing support; OAM&P support; connection to public switched telephone network; control CoS/QoS parameters; and enhanced services.

The voice gateway (VG) 232 may be connected to the public switched telephone network 160 and operate to convert between IP based voice packets and standard public switched telephone network 160 voice traffic. Voice gateway 232 may be configured as multi-frequency (MF) or ISUP gateways on a per-T1 basis. Where multi-frequency (MF) trunks are used, one embodiment utilizes signaling between the call manager 218 and the voice gateway 232 using MGCP, SIP, H.GCP and/or other compatible protocol. Multi-frequency trunks may be compatible with Feature Group D (FGD), Operator Service (OS) Signaling protocol and/or Termination Protocol (TP).

The IP central station 200 may be variously connected to the public switched telephone network. For example, the IP central station 200 may be connected directly to the public switched telephone network using, for example a bearer channel (e.g., a T1 or T3 carrier) and/or interconnected using one or more networks such as an IP network and/or ATM/frame/cell relay network 185. Where a T1 network is utilized, it may be desirable to utilize one or more of ISUP or MF, FGD, and OS to interconnect a service bureau in the public switched telephone network 160. Alternatively, the service bureau in the public switched telephone network 160 may be interconnected using an alternative network arrangement such as an IP network 120 and/or a ATM/frame/cell relay network 185. The service bureau may coordinate with the IP central station 200 in providing operator services, directory services and provisioning for 311, 611, and 711 services. Emergency 911 services may be routed to an E911 tandem switch that has the appropriate databases and interfaces with a Public Safety Answering Position (PSAP). Emergency 911 services may be coordinated by the call manager 218 and/or public switched telephone network based service bureau.

Voice gateway 232 may be router-based and include one or more voice feature cards and/or DSP Module cards to perform voice processing. The voice gateway 232 may optionally include host processors, LAN/WAN ports, Ethernet ports, T1 or E1 telephony interface cards, Voice Feature Cards with DSP Modules providing voice compression transcoding (G.711 and G.729), carrier-quality echo cancellation with 8 ms-32 ms tail length, a de-jitter buffer which adapts to delay variations in the network in order to minimize the delay, packet loss concealment that generates concealment frames for lost packets using information from previously received data, and/or tone detection and generation. This function detects Multi-Frequency (MF) tones and generates MF and call processing tones (e.g. dial tone, call-waiting tone etc.).

In exemplary embodiments, the voice gateway 232 may include T1/E1 interfaces with internal Channel Service Units (CSUs). It may also be desirable to configure the voice gateway 232 such that ISUP, MF and Centralized Attendant Services (CAS) trunks are supported with a configuration done on a per T1 basis. Additionally, multi-frequency tones and Centralized Attendant Services may utilize a “robbed bits” communication scheme where bits are “robbed” from sub-frames to transmit in-band signaling. The multi-frequency tones may be converted to and/or from Open Gateway Control Protocol which includes, for example, simple gateway control protocol (SGCP) signal requests and events by the voice gateway 232, MGCP, HGCP/H.248, packet cable standardized protocols, etc. For example, multi-frequency tones and/or lower level signaling and timing functions may be translated to and/or from any of the following indications: simple gateway control protocol Notify functions, simple gateway control protocol Notification Requests, Connection requests, Modify Connection requests, off-hook and/or on-hook indications.

An Ethernet interface with a RJ-45 connector may be used to connect the voice gateway 232 to the central router 210 (e.g., Gigabit Switch or High Speed Router (HSR)). The multimedia gateway control protocol may be used as the interface between the voice gateway 232 and the call manager 218. For example, call control, signaling, and multimedia data stream, real time protocol (RTP) connections, IP addresses, UDP ports, codec choice etc, may be configured in any suitable manner such as by using a multimedia gateway control protocol. In exemplary embodiments, audio streams may be passed directly between customer premises equipment 102 using real time protocol connections over, for example, a user datagram protocol (UDP). Thus, the multimedia gateway control protocol may be utilized to request the voice gateway 232 to initiate, cancel, and/or otherwise modify connections in order to set up and tear down RTP media streams. A similar procedure may also be utilized to request continuity tests and results.

In exemplary embodiments, it may be desirable to adapt the IP network to carry signaling system 7 (SS7) Transaction Capabilities Application Part (TCAP) messages over the IP network 120 and/or the ATM/frame/cell relay network 185. The transport of signaling system 7 (SS7) transaction capabilities application part (TCAP) messages over the packet networks allows signaling operations to be supported by multiple connections to the same host, multiple host connections, and distributed processing of call set-up information using, for example, multiple call managers 218 in the broadband network 1. Thus, the IP network 120 and/or ATM/frame/cell relay network may be utilized to interconnect a plurality of ESS switches to transport signaling information, voice, and/or data. In embodiments where the signaling gateway (SG) 234 is configured to support signaling system 7 (SS7) signaling transport using transaction capabilities application part (TCAP) messages, it may be desirable to include a translator for converting between multimedia gateway control protocol (MGCP) messages and transaction capabilities application part (TCAP) messages and/or ISDN User Part (ISUP) messages.

The point where ISUP and TCAP messages are terminated at a signaling system 7 (SS7) signaling gateway is defined as a Service Switching Point (SSP) to the signaling system 7 (SS7) network 170. The call manager 218 may be configured with a standardized Application Programming Interface (API) to allow interaction with the signaling system 7 (SS7) by, for example, sending and/or receiving ISUP and TCAP messages from a service switching point (SSP). Full class 5 signaling system 7 (SS7) functionality may be included in the call manager 218 including the ability to provide all of the information necessary for billing as defined in the GR-246-Bellcore standard. The signaling gateway 234 may be arranged to perform: signaling system 7 (SS7) message handling (message discrimination, message distribution, and message routing); signaling link management (e.g., link activation, deactivation); signaling route management (managing Point Code [PC] route status based on route received management messages such as Transfer Prohibited, Transfer Allowed, Transfer Restricted, etc.); and signaling traffic management (diversion of traffic based on unavailability, availability, restriction of signaling link, route, and Point Code.) The signaling system 7 (SS7) architecture supports the necessary redundancy component scheme for system reliability and availability during scheduled maintenance and/or software/hardware upgrades. The signaling gateway 234 may be configured to directly provide for lower level signaling system 7 (SS7) processing.

In exemplary embodiments, the signaling gateway 234 interacts with the call manager 218 using an appropriate open interface (e.g., Common Object Request Broker Architecture (COBRA)). In these embodiments, it may be desirable for translation software in the signaling gateway 234 to add Message Transfer Part (MTP) layer information to the ISUP and/or TCAP data to create a complete signaling system 7 (SS7) message. The complete signaling system 7 message may then be sent to the Signaling Transfer Point (STP) in the external signaling system 7 (SS7) network 170. Conversely, the signaling gateway 234 may be configured to remove ISUP or TCAP application layer data from the signaling system 7 (SS7) messages received from the STP prior to converting the information to an appropriate open interface (e.g., COBRA) and forwarding the information to the call manager 218 via the central router 210.

The accounting gateway (AG) 240 may be configured to receive messages representing events from the call manager 218 via a suitable transport mechanism such as the central router 210. Typically, two messages are received for each call, the first when the call is established, and second when the call terminates. In the case of unsuccessful calls, only the failure message will be logged. The messages provide details about the calling and called parties, the timing of the call set-up, the duration and the quality of the call. Accounting gateway 240 may be duplicated using a redundant computer, with each gateway having dual-mirrored disks. The accounting gateway 240 stores usage records and may then distribute them to linked destinations (e.g., billing centers) for processing. Billing centers typically include bill processors that receive accounting information from the accounting gateway 240 and generate appropriate on-line or paper billing to customers. The accounting gateway may be configured to accommodate multiple days worth of accounting records such as the records for one day, two days, three days, four days, a week, or a month. The period in which the data is retained in the accounting gateway may be dependent on business needs, hardware restrictions, and/or the billing cycle. For example, as the end of the billing cycle nears, it may be desirable to shorten the period the accounting gateway holds the data such that calls placed the day the bills are printed are included on the bills. Further, the accounting gateway may both retain and forward data to the billing centers. In this manner, if the equipment at the billing center fails, the accounting gateway 240 may serve as a backup. Similarly, the billing center may act as a backup where the accounting gateway 240 fails.

An Automatic Message Accounting (AMA) format is typically used by circuit-switching systems, packet-switching systems, and other network elements to provide billing usage measurements data (e.g., the Bellcore® Automatic Message Accounting Format (BAF)). This data may be utilized either to permit charging the customer for use of network resources or to permit charging other carriers (e.g., InterExchange Carrier (IEC) and other Local Exchange Carrier (LEC)) for assistance in placing call connections. The accounting gateway 240 may be configured to convert this information into an Automatic Message Accounting Format (AMA) Format (e.g., BAF) records and send these records to the external billing systems using, for example, a TFTP (trivial file transfer protocol). Time-stamp accuracy is typically based on the accuracy of the call manager 218 clock which may be derived from the TOD 212 server. To create appropriate AMA records, the event information produced by the call manager 218 preferably has appropriate information for the telephone service specified such as phone number of the calling party (customer), phone number of the called party (customer), time of call, duration of the phone call, and use of any discretionary features. Different AMA structures may be generated between On-Net calls (defined as within a network service provider IP network 120) vs. Off-Net calls (defined as outside of service provider IP network—e.g. public switched telephone network) for billing purposes.

The element management gateway (EMG) 238 may provide system management functionality that includes, for example: a) status and performance monitoring for the Operation Administration, Maintenance, and Provisioning center, to gauge the ongoing operation of applications; b) extensive information exchange with a network operations center responsible for ongoing maintenance of one or more applications; c) customizable operations interface to allow the network operations center to view only information required, thus reducing the time spent filtering information; d) centralize distributed application configuration allowing for the centralized configuration of objects residing on a plurality machines; e) proactive network management capabilities to remove the need for constant operator intervention making the day-to-day operations more efficient; and/or f) intelligent display of status information to separate critical issues from low-priority problems allowing the operation center to assign resources to the right problems at the right time.

The multimedia gateway (MG) 230 may be configured to connect to the public switched telephone network 160 and to convert IP based multimedia packets into standard public switched telephone network 160 traffic. The multimedia gateway 230 may include an intelligent trunking interface that communicates with the call manager 218 for automatic trunk sizing and allocation between the IP network 120 and the public switched telephone network 160. For example, when an system user at the customer premises is using a PC and/or a multimedia phone to communicate with a traditional public switched telephone network 160 user, the communication session involves the transmission of video and audio data. The bandwidth that is required for this type of communication is much greater than that required for a PSTN-to-PSTN voice call or an IP-to-PSTN voice call. The multimedia gateway 230, as the interface between two systems, may negotiate a larger bandwidth to facilitate the call if the called party is also video enabled. This bandwidth negotiation process typically occurs with a 5ESS or a Local Digital Switch within the public switched telephone network 160. Typically, a multimedia call, including live video, audio and data, will require bandwidth ranging from 56 K to 1.544 Mbps. However, as the number of users sharing the same link grows, the quality of the transmission deteriorates significantly. The multimedia gateway 230 must be able to monitor bandwidth usage and make appropriate adjustments so as to maintain an acceptable quality of service. Further, it may be desirable for the call manager 218 and the multimedia gateway 230 to communicate between themselves and/or the customer premises equipment 102 to determine whether the user has authorized the additional bandwidth and hence expense of the call. For example, even where a called and/or calling party is video enabled, it may nonetheless refuse to authorize payment for the increased bandwidth necessary for video.

The Internet gateway (IG) 236 may be connected to the Internet (e.g., World Wide Web (www)) and provide a means for IP based data packets to be routed between the IP network 120 and the Internet 180. Alternatively, IP based voice packets may be routed via the Internet 180. In exemplary embodiments, the Internet gateway 236 routes data-only packets which share the same priority level with other lower priority, non-real-time traffic consistent with computer data communications presently experienced with the Internet 180. Consequently, low priority and low latency data traffic on the IP network 120 utilize the Internet gateway 236 to communicate with other IP data networks such as the www. Voice packets may be routed through another network such as the ATM/frame/cell relay network 185, a private IP network 120, and/or the public switched telephone network 160 where committed information rates may be easily obtained.

In exemplary embodiments, the broadband network 1 includes the interfaces which enable connections to existing Operation, Maintenance and Provisioning (OAM&P/OSS) 195 systems that support, billing, accounting, provisioning and/or configuration management functions. A Secured Management Data (SMD) Network 190 may be utilized to connect the OAM&P 195 to the accounting gateway 240 and element management gateway 238. The Secure Management Data network 190 may include a Network Service Division's NSD Net. The Secure Management Data network 190 helps ensure that only secure communication can occur between the IP central station 200 and the OAM&P 195. This eliminates one potential means of tampering with the billing and provisioning functions in the OAM&P. The billing systems (OSS) 195 may include the Network Operations Center (NOC). The NOC may include a translation server which includes functions for allowing communications and control of diverse networks.

B. BROADBAND RESIDENTIAL GATEWAY (BRG)

Referring to FIG. 3, a preferred embodiment for a broadband residential gateway (BRG) 300 will now be described and explained. The broadband residential gateway 300 may be configured as the interface unit between the remainder of the customer premise equipment 102 devices and the external network. The broadband residential gateway 300 may be connected to the remainder of the broadband network 1 using any suitable mechanism such as a gateway directly into an IP network and/or a cable connection. In the most preferred embodiments, a hybrid fiber-coaxial plant connection is utilized such as hybrid fiber-coaxial (HFC) plant 112. The hybrid fiber-coaxial plant 112 allows numerous broadband residential gateways 300 to be included on an existing hybrid fiber-coaxial plant 112 without modification to the plants infrastructure.

The broadband residential gateway 300 may be variously configured to, for example, provide high-speed cable modem capabilities to interconnect one or more associated PCs with each other and with the remainder of the broadband network 1, provide functionality to one or more TVs (using, for example, either an integrated or separate decoder functionality, e.g., set top box 350), one or more telephone connections such as plain old telephone service (POTS) phones and/or digital telephones, displays, wireless interfaces, voice processing, remote control interface, display interface, and/or administrative functions. In exemplary embodiments, the broadband residential gateway 300 may a) providing conversion between analog voice and IP voice packets, b) multiplexing/demultiplexing streams of IP voice packets, c) supporting multiplexing/demultiplexing of multiple incoming and outgoing signals including multiple voice, multimedia, data, system administration, and/or TV information signals.

Where the elements of the broadband residential gateway 300 are interconnected, the interconnection may be provided by one or more data buses, for example, a high speed bus (HSB) 360, processor bus 380, and/or other interconnection system. The high speed bus 360, 380 may be configured to provide a flexible conduit for transferring information between the internal hardware, processors and ports. In exemplary embodiments of the broadband residential gateway 300, the high speed bus 360 may include one or more of the following functional units a) a universal remote control receiver module 365 for receiving wireless (e.g., infrared, and/or RF) signals (e.g., keyboard signals and/or remote control signals) for control of the broadband residential gateway 300 and/or any connected devices, b) a display, display driver, touch screen logic module for driving one or more local and/or remote displays for interfacing with the broadband residential gateway 300 and/or one or more connected devices, c) one or more TV port modules 336 for interconnecting televisions, set-top devices, and/or other audiovisual devices to the broadband residential gateway 300, d) one or more data port modules 334 for connecting/interconnecting data enabled devices (e.g., personal computers, palm top devices, etc.), e) one or more telephony port modules 332 for interconnecting one or more analog and/or digital telephones, f) one or more peripheral port modules 342 for interconnecting one or more peripheral devices such as disk drives, data storage devices, video cassette recorders, DVD devices, audio devices, video devices (e.g., camcorders, digital cameras, digital video recorders, stereos, etc.), g) one or more external/internal intercom modules 344 for interconnecting remote intercom and/or security monitoring devices, h) one or more wireless interface modules 345 for interconnecting with various wireless extension devices such as wireless TVs, cordless and/or wireless telephones, wireless LANs, etc., i) one or more voice recognition/voice synthesis modules 355 for generating voice announcements, voice messages, and voice prompts and for recognizing voice generated commands and data, j) set-top box module 350 for performing the functions associated with a set-top box locally and/or for communicating with one or more remotely coupled set-top boxes, k) memory 322 (e.g., DRAM, RAM, flash, and/or other memory) for storing information and operating data within the broadband residential gateway 300, l) transceiver 302 for communicating with one or more external broadband networks m) operating program store 330 (e.g., ROM, flash, etc.) for storing at least portions of the operating programs for the broadband residential gateway 300 and/or interconnected devices, n) security processor, smart card and/or credit card interface module 340 for providing secure processing functions and/or credit card/smart card transaction functions, and/or o) distributed processing controller 306 which may be a microprocessor and/or one or more interconnected distributed processing modules for controlling the broadband residential gateway 300. Where the distributed processing controller 306 includes one or more distributed processing modules, the modules may include a telephony processing module (P1) 308, data processing module (P23) 310, video processing module (P3) 312, auxiliary processing module (P4) 314, IP processing module (P5) 316, and/or an operations administration maintenance and provisioning processing module (P6) 318 interconnected through one or more busses such as processor bus 380. The processor bus 380 and/or high speed bus 360 may include any suitable interconnect bus including intelligent bus configurations incorporating smart buffer logic (not shown in FIG. 3) to facilitate data transfer between interconnected processors and/or modules. The various modules and/or processing components of the broadband residential gateway 300 may be powered by, for example, a power supply unit (not shown). Each of the individual modules of the broadband residential gateway will now be described in more detail.

The transceiver 302 may include circuits for converting digital signals to and from RF signals suitable for transmission across a broadband network such as the hybrid fiber-coaxial plant 112. The transceiver 302 may include one or more input/output ports such as a cable interface (e.g., an F connector cable connection) and/or a fiber optic interface connected to a communication media (e.g., hybrid fiber-coaxial Plant 112). The transceiver 302 may be compatible with the DOCSIS 1.0 or later specifications. For signaling purposes, the broadband residential gateway 300 may be compatible with the Media Gateway Control Protocol (MGCP) or other compatible signaling protocol (e.g., SIP or H.GCP) to support telephony applications. The transceiver 302 may serve as a modem, a translator and/or a multiplexor/demultiplexor. Data received from the network may be de-multiplexed and placed on the data bus for dispatch to the appropriate peripherals and/or ports. Data from the various ports and peripherals may be multiplexed together for distribution over one or more broadband networks (e.g., the hybrid fiber-coaxial (HFC) plant 112). Where a hybrid fiber-coaxial plant 112 is utilized, the data may be multiplexed onto various frequency bands of the hybrid fiber-coaxial plant 112 in a continuous data stream(s) and/or packetized data stream(s). To facilitate data transfer for various networks, the transceiver 302 may be include one or more registers for data queuing and/or IP tunneling of data packets across the broadband network.

Although the illustration of a display, display drivers, and touch screen logic device 338 suggests that the a display is integral to the broadband residential gateway 300, alternative embodiments of the broadband residential gateway 300 may provide a user interface via the TV screen, PC screen, video telephone, and/or other display device in addition to, or in lieu of, a display integral to the broadband residential gateway 300.

The peripheral ports module 342 may include a plurality of ports providing connectivity to external peripherals. Exemplary interfaces include, PCI, Firewire, USB, DB25, etc. Devices which incorporate one or more of these interfaces may utilize the broadband residential gateway 300 to interconnect to the remainder of the broadband network 1.

The external/internal Intercom Module (IM) 344 may include one or more microphones/speakers, voice CODECs, telephony processors, and/or interface ports. Where an intercom module 344 is utilized, the built-in circuitry may be configured to detect, for example, unused plain old telephone system telephone(s) and generates a special intercom tone on these unused telephones. In this manner, existing plain old telephone system telephones, digital phones, and/or other devices may serve as an intercom throughout the residence. The controller 306 (e.g., such as the P1 telephony processor 308) may function to command the intercom module 344 to determine an appropriate intercom path to select an intercom connection between various locations. In exemplary embodiments, the CODEC may be configured to convert the analog voice signal into IP packets for transmission over one or more data ports 334, TV ports 336, display modules 338, telephony ports 332, peripheral ports 342, external/internal intercom ports 344, wireless interface ports 345, and/or set-top boxes 350.

In yet further embodiments, multiple broadband residential gateways 300 may be configured through, for example, IP tunneling, to set-up an intercom connection between multiple remote broadband residential gateways 300. In this manner, an administrative assistant at the office may be contacted via an intercom connection present at the users home. Thus, one or more individuals disposed at either local and/or remote locations with diverse types of equipment may communicate as an intercom group without the need to communicate via normal dialing procedures.

In addition to intercom services, the intercom module 344 may also configure intercom services for other telephony services (e.g., extension transfer, call conferencing, internal caller ID), high speed data services (e.g., LAN connections), facsimile transmission/reception, e-mail transmission/reception, video conferencing, and/or CATV/HDTV (Cable Television/High Definition Television) using standard industry protocols such as DOCSIS 1.0 or higher and IP tunneling transmissions. These services are advantageous in that once configured, the user may simulate a work environment in his home.

Though processing may be accomplished by a single processor performing all functions (e.g., processing controller 306), in the preferred embodiment shown in FIG. 3, the architecture employs a distributed processing controller 306, and a plurality of processors P1-P6 308-318. In the distributed processing architecture, each of the plurality of processors P1-P6 may be configured to have a dedicated function to provide predetermined services or applications. The processors may be coupled together via any suitable mechanism such as the processor bus 380 and/or high speed bus (HSB) 360. The first processor P1 308 may include telephony applications such as call set-up, call tear down, and call functions; the second processor P2 310 may include management functions such as distribution and coordination of data within the various devices of the broadband residential gateway 300; the third processor P3 312 may include video processing functions for configuring control panels, screen displays of attached devices, video conference calls, MPEG decoding functions and other video processing functions; the fourth processor P4 314 may include an auxiliary processor for off loading special processing functions such as numeric processing; the fifth processor P5 316 may include interface input/output processing (e.g., text to voice and vise versa) and/or Internet protocol (IP) processing functions for configuring data to communicate with the remainder of the broadband network 1 and/or devices attached to the broadband residential gateway 300 such as IP telephones or IP enable PCs; and the sixth processor P6 318 may include processing functions for Operation, Maintenance and Provisioning (OAM&P) processing. Each of the above processors may be an entirely separate processing unit with included RAM, ROM, Flash memory, or may share RAM, ROM, and/or Flash memory. Where shared RAM, ROM, and/or Flash memory is utilized, the memory may be located within the distributed processor controller 306 and/or on the processor bus 380. Alternatively, the memory may be integrated into the operating program store 330 and/or into memory 322.

The Distributed Processing Controller 306 with its associated processors (P1-P6) may be coupled to the various elements of the broadband residential gateway 300 so as to enable proper operation of each of the individual components. For example, the distributed processing controller 306 (with any associated processors (P1-P6)) may also coupled to the security processor, smart card/credit card, and interface module 340, the peripheral port(s) module 342, and/or the External/Internal Intercom Module 344 for providing control and coordination among devices coupled to the high speed bus 360.

The display 338 may include, for example, an interactive LED/LCD module positioned in a suitable location such as within or attached to the broadband residential gateway 300. The display 338 may include an interface to notify, display and receive user inputs and processing status. The display 338 may be configured to display various informational status such as multimedia mail, called ID, call logs, call in progress and associated information, call waiting information, call conferencing, and/or other call related information. The display 338 may provide a display of real time status of the various devices connected to the broadband residential gateway 300 as well as any current connections, calls, and/or data transfers. The display 338 may also include touch screen capabilities that allow information to be input via a plurality of interrelated on-screen prompts, on-screen icons, and/or a keypad (e.g., an alphanumeric keyboard). The keypad may be a remote control, numeric keyboard, and/or alphanumeric keyboard.

In one embodiment of the display 338 operation, a user may touch an icon representing a pending voicemail and/or multimedia mail message. The panel may be configured to send an electronic signal to the processing controller 306 and/or an attached processor such as the telephony processor. On receiving the signal, the P1 telephony processor 308 may be configured to generate an IP packet via the transceiver 302 across portions of the broadband network 1 to the multimedia server 222 in IP central station 200. The multimedia server 222 may authenticate the request by, for example, verifying location of the request and/or the identity of the requesting party. Where identity of the calling party is being verified, the user enters an access password by an audio and/or keyboard request. Where an audio request is generated, the user may utilize the external/internal intercom module 344 of the broadband residential gateway 300, or via a text message entered into the display 338. The user may then enter the appropriate access code via the onscreen soft keypad, microphone, and/or keyboard. Alternatively, the message could be stored locally in the broadband residential gateways 300 memory 322 and depending on whether there is a password lock on the broadband residential gateway 300, the user may not have to enter a password to access the message. Where the message is stored locally in the broadband residential gateways 300 memory 322 rather than IP central station, the display 338 simply recalls the message from memory and presents to the user to provide one-touch instant message retrieval.

In embodiments where the broadband residential gateway 300 supports multiple mailboxes, the icons on the LCD/LED may be personalized to show the identity of the owner of the message. Each user may have a different password to ensure privacy of access. An activity log which tracks past and present messages and/or archives multimedia messages may be presented on display 338. The archive may be stored locally, or at a remote location such as IP central. The archive may be utilized by the user to recall messages which have long since been erased from local storage but may be retrieved from IP central on tape and/or disk storage. This is preferably an optional feature for those users who are less security conscious. The multimedia messages need not be displayed only on display 338. In alternate embodiments, any of the peripheral devices attached to the broadband residential gateway 300 are capable of receiving the multimedia messages.

The memory 322 may be variously configured to include one or more field-upgradeable card slots for permitting memory expansion. Certain users may wish to enable higher end applications such as near video on demand (e.g., pausing of shows via buffering in memory), video conferencing of multiple users, multi-party conferences, call waiting for multiple parties, etc. Accordingly, the use of a broadband residential gateway 300 allows the user to upgrade memory via inserting additional cards. Alternatively, the user may use system memory in IP central and buffer data remotely.

Operating program store 330 may be configured to receive updates. This may be accomplished by having the user replace one or more memory cards or automatically by the IP central station downloading new operating code into one or more residential gateways 300.

As previously indicated, smart buffer logic (SBL) may be coupled to the telephony port(s) 332, data port(s) 334, TV port(s) 336, peripheral port(s) 342, and/or the distributed processing controller (DPC) 306. Where the smart buffer logic is utilized, it may function to buffer the IP packets for delivery over the communication network such as the hybrid fiber-coaxial plant 112. In addition, the smart buffer logic may include selectable switching and routing algorithms based on services and applications associated with each port. Depending on the destination of the IP traffic, the smart buffer logic may multiplex signal from various devices to effect faster information transfer. The smart buffer logic may also allow direct memory access between memory 322 and one or more of the devices and/or ports coupled to the high speed bus 360.

The telephony port(s) 332 may include various interface circuitry (e.g., analog interface, logic and firmware for interfacing with the Plain Old Telephone (POTs) telephones). Also the telephony port(s) 332 may also be configured to include user interface logic, voice processing logic, voice activity detector logic, voice CODECs, and DTMF (dual tone multi-frequency) tone sensing logic. Echo cancellation and automatic gain control may also be utilized in the telephony port(s) 332 circuitry. In one embodiment, RJ-11 connectors for a plurality of lines (e.g., 4) are provided for connection to one or more existing plain old telephone system 110 telephone units. However, the broadband residential gateway 300 may contain any number of telephone connection ports. In this manner, any number of existing user phone may connected directly to the broadband residential gateway 300 without modification. Alternatively, the broadband residential gateway can be configured to support, in addition to or as alternative to the plain old telephone system telephone units, ISDN telephones and/or other digital phones (e.g., IP telephones) using an appropriate interface.

The data port(s) 334 interface may be variously configured. In one configuration, the data ports include high speed data service connections to, for example, a personal computer (PC) using a LAN connection. For example, the data ports 334 may include an Ethernet 802.3 connection compatible with category 5 unshielded twisted pair (UTP) cable and a RJ-45 connector. The data port(s) 334 may include the necessary interface circuitry for coupling to remote computers.

The TV port(s) 336 may include an interface for conventional television, HDTV and/or CATV services. The TV port(s) 336 typically have one or more F-connectors used for coaxial cable connection to a TV set(s). The TV ports may be configured to connect to a set top box (STB) via the F-connector or directly to a remote television. In embodiments where the settop box is co-located with the television, the data supplied over the TV ports may be either analog and/or digital information. Where the settop box is integrated into and/or comprises the broadband residential gateway 300, the TV ports may be analog or compatible with HDTV signals.

The broadband residential gateway 300 need not necessarily be limited to home use and is intended to also be utilized in business applications. In some configurations, the broadband residential gateway 300 may serve the same functions and operate as a private branch exchange (PBX). Where greater capacity is desired, one or more broadband residential gateways 300 may be disposed on a PC card and combined in a PC, rackmount, and/or server to create an expandable private branch exchange type system that enables intra-premises calling between telephones connected to various telephone connectors on the broadband residential gateway 300.

C. INTEGRATED BROADBAND IP BASED COMMUNICATION SYSTEM

FIG. 4 shows an exemplary embodiment of the broadband network 1 shown in FIGS. 1-3, with like components identified with identical numbers. At the extremities of the integrated communications system is the customer premises equipment unit (CPE) 102, e.g., one or more customer premise equipment 102 at each customer location. The customer premise equipment 102 may be configured to include an integrated communication interface device such as the broadband residential gateway 300. Other customer premise equipment 102 devices such as one or more televisions (TV) 106, personal computers (PC) 108, and telephones 110, etc., may be connected to the broadband residential gateway 300 via various ports as discussed above. The customer premise equipment 102 could include multiple TVs 106, telephones 110, and PCs 108 connected to a single and/or multiple broadband residential gateway 300. Further, in certain embodiments, it may be desirable to divide the broadband residential gateway 300 into more than one physical package. In this manner, certain interface circuitry may be located outside of the home while various processing circuitry may be located near a peripheral device such as in a settop.

Where the broadband residential gateway 300 is coupled to the hybrid fiber-coaxial plant 112 in accordance with a preferred embodiment of the present invention, it may be configured to provide the user with both information data (e.g., through an Ethernet interface), telephony access, and TV service (e.g., HDTV, Digital TV and/or CATV services). In exemplary embodiments, the hybrid fiber-coaxial plant 112 typically includes both coaxial cable and optical fiber networks, though, where desired, the network may include only coaxial cable or optical fiber. The hybrid fiber-coaxial plant 112 may be coupled to a head-end hub (HEH) 115. The head end hub 115 may provide an interconnection point to gather and/or transform external services (e.g., off air and satellite video, public switched telephone network voice, and Internet data) into a format suitable for distribution on the hybrid fiber-coaxial plant 112 for use with the customer premise equipment 102. The head-end hub 115 may include one or more cable modem termination systems (CMTS) 116 coupled between the hybrid fiber-coaxial plant 112, a Head-end (HE) 117 and/or an Edge Router (ER) 118. The edge router 118 may be coupled to the cable modem termination system 116 and to one or more ultra high speed routers (UHR) 121. One or more ultra high speed routers 121 may be interconnected to each other and/or through a centralized mechanism such as an IP network database to form a high speed network. The high speed packet network 120 n is one example of the network 120 (e.g., IP network) shown in FIG. 1.

In the embodiment shown in FIG. 4, the high speed network 120 n includes the ultra high-speed routers (UHR) 121 configured in a ring configuration. Although this embodiment shows the use of the IP network database (IND) 122, other configurations are also suitable. Where an IP network database 122 is utilized, it may be desirable to incorporate one or more data sets such as: a IP local number portability database (IP LNP) 122 a which may be utilized for transferring local DN among service providers when a user changes their service provider; an IP caller name database (IP CNAME) 122 b which may be utilized to provide a database of names relating to IP addresses and/or domain names; an IP line information database (IP LIDB) 122 c which may provide alternative billing and allow flexibility in determining who pays for a call; and an IP 1-800 Database (IP 8YY) 122 d which may provide a database of 1-800 numbers relating to the IP network 120 a. Alternatively, the IP local number portability database may be located at another location, such as at an IP central station (IP Central) 130. Where desired, a local service management system (LSMS) 150 may be arranged to provide management of the IP local number portability database. Where a local service management system 150 is utilized, a plurality of local service order administration (LSOA) units 152 may be coupled to the local service management system by, for example, a number portability administration center (NPAC) 151. In this manner, directory numbers may be transported among different service providers. In such a case, a NPAC 151 is generally coupled to the LSMS 150 and uses the LSMS 150 to synchronize the numbering databases and to coordinate the porting process.

As indicated above, the broadband network 1 may include a plurality of interconnected high performance networks 120 n. Each high performance network 120 n may include a separate IP central station 200 and/or share a single IP central station. Having distributed IP central stations located throughout the broadband network 1 provides improved performance and quicker response time for an individual user. Although not illustrated, each high performance network 120, 120 n may be connected to multiple head-end hubs 115, each head-end hub 115 may be connected to multiple hybrid fiber-coaxial plants 112, and each hybrid fiber-coaxial plant 112 may be connected to a plurality of customer premises equipment 102, each containing one or more broadband residential gateways 300. The plurality of high performance networks 120 n may be configured as an interconnected network for routing packetized information from point-to-point in accordance with a desired destination.

The high performance network 120 n may be configured to provide connectivity for and between a plurality of head-end hubs 115 and/or a plurality of broadband residential gateways 300 and other networks such as the Internet, e.g., www 180, the public switched telephone network (PSTN) 160 and/or various signaling systems such as the SS7 network 170 for end-to-end voice over IP applications. The IP central station 200 may be configured to provide seamless integration and control of the high performance network 120 (e.g., an IP based communication system) interface with the public switched telephone networks (PSTN) 160, signaling system seven (SS7) 170, and/or the Internet 180 so that packetized data, voice calls, and other signaling information is properly transferred between the broadband residential gateway 300 and the public switched telephone network 160 and Internet 180. In certain configurations, the hybrid fiber-coaxial 112, head-end hub 115, and high performance network 120, provide a signal conduit for packetized voice and data which may, with the coordination of the IP central station 200, be provided in the appropriate format between the broadband residential gateway 300, the public switched telephone network 160, and/or the www 180.

D. GENERAL OPERATION OF INTEGRATED COMMUNICATION SYSTEM

The typical home user is currently required to purchase multiple intelligent data conduits such as multiple set-top boxes, a plurality of conventional, DSL and/or ISDN phones, cable modems, HDTV receivers, satellite receivers, home PC LANs, etc. The integrated communication system of the present invention provides a user friendly versatile communication system that enables voice over IP telephony, information data (e.g., PC and Internet), and television services in a system with one intelligent customer premise equipment 102 interface, the broadband residential gateway 300. The broadband residential gateway 300 in conjunction with the IP central station 200 provides a flexible communication system that can provide any number of integrated communication service features and functions without requiring the user to become familiar with numerous, diverse types of equipment.

In one exemplary application of the voice over IP operations, the broadband residential gateway 300 digitizes the analog telephony signal using, for example, G.711 μ law coding (64 Kbps Pulse Code Modulation). The digital samples may then be packetized in, for example, the broadband residential gateway 300 into IP packets. The broadband residential gateway 300 may be configured to encapsulate the IP packets into, for example, DOCSIS (Data Over Cable Service Interface Specifications) frames for transmission back to the head-end hub (HEH) 115 over the hybrid fiber-coaxial plant 112. The hybrid fiber-coaxial plant 112 may then be configured to transport signals for both upstream (to head-end hub 202) and downstream (to the broadband residential gateway 300 and customer premise equipment 102) directions. Although the DOCSIS protocol is utilized in this example, any future protocol may also be used for the digitizing and packeting of data. Where the protocol changes, it may be desirable to download new operating code from, for example, IP central station 200 to the individual broadband residential gateways 300, to update the communication protocols dynamically. When new protocols are adopted, the IP central station may utilize, for example, the system management server 216 to download new protocol data into, for example, the protocol manager in the call manager 218 and the program store 330 in the broadband residential gateway 300.

Where voice packets are sent over constant bit rate (CBR) channels using unsolicited grants, additional packet data channels may be used to support signaling messages (e.g., SGCP, Simple Gateway Control Protocol), high-speed cable modem service and/or other upstream packet data services. The upstream packet data services may be sent using available bit rate (ABR) channels such that the voice channels not impacted by data traffic.

A. TV SIGNAL RECEPTION

The head-end 117 may originate CATV signals for transmission over the distribution network. However, in alternate embodiments, signals may be inserted at other points in the distribution network, such as at various hubs or may arise at remote locations in the network such as IP central. Down stream channels may be utilized to facilitate the transmission of signals from the head-end or other input distribution point to the subscriber premise. Where analog RF signals arrive at the broadband residential gateway 300 of the customer premise equipment 102, typically, the transceiver circuitry 302 will detect if the signal is addressed to this broadband residential gateway 300. If so, the transceiver will allow reception of the RF signal. Upon conversion to a digital format, the signal is typically output over the high speed bus (HSB) 360 to one or more associated devices for processing. For example, where the signal is a TV signal, the signal may be output directly to the TV port 336 and/or processed by the settop box 350 prior to outputting to the TV ports 336 and/or display 338. Where user channel selection is preformed directly in the broadband residential gateway 300, channel selection may be preformed by remote control receiver 365 using an external device such as a remote control. The remote control receiver may receive a plurality of individually coded remote control commands from different receivers and process the signals for only one associated device in accordance with the received commands. Alternative channel inputs include the display 338 and/or any associated keypad. Authorization to certain channels may be controlled by security processor 340.

Where a remote settop box is utilized, the box may be coupled directly to the HFC for individual frequency tuning and/or receive a digital feed from the broadband residential gateway 300 after decoding the digital signal. For example, where hybrid fiber-coaxial plant 112 contains fiber connections to locations near the individual homes, it may be desirable to download one or more simultaneous individually requested programming stream(s) and/or digital data stream(s) to the broadband residential gateway 300. In this manner, the number of channels, movie selections, and/or entertainment options available to the user are unlimited. Cost is minimized since only a single intelligent user interface is used in the home and all televisions, phones, computers, and/or other user interface devices use the same intelligent user interface to the broadband network 1. In this manner, the broadband network 1 may offer premium television, voice and/or data services to multiple conventional televisions, phones, and PCs without the use of multiple set boxes, modems, and external connections. Thus, the users are provided a single unified interface to satisfy their external data needs.

B. EXEMPLARY CALL FLOW OF AN ON-NETWORK CALL TO AN OFF-NETWORK CALL, WITH THE OFF-NETWORK CALL INITIATING THE DROPPING

FIG. 5 illustrates an exemplary call processing sequence for an on-net call (e.g., an IP based call) to an off-net call (e.g., a public switched telephone network based call), in which the off-net party initiates the drop call sequence. The exemplary call processing sequence operates as follows:

1. Once the broadband residential gateway 300 detects an off hook condition, the broadband residential gateway 300 may generate an off hook signal 508 to the call manager (CM) 218. The off hook signal acts as a dial tone request to the call manager 218. Alternatively, the broadband residential gateway 300 may collect all dialed digits before activating the off hook condition. This alternative may be desirable to save resources at the call manager 218 where multiple incoming lines are available to handle any additional calls. Thus, even though one phone is off-hook, the broadband residential gateway 300 determines that other lines are available and does not initiate the off-hook signal until all dialing digits have been collected.

2. Where the call is managed entirely by the call manager, the call manager 218 will issue a dial tone message 509 to the requesting broadband residential gateway 300 in order for the broadband residential gateway 300 to generate a dial tone to the associated phone. Where the broadband residential gateway 300 shares management of the call, the broadband residential gateway 300 generates the dial tone in response to the off-hook condition.

3. Where the call is managed entirely by the call manager 218, the call manager 218 will then enter a state where it polls and collects the dialed digits 510 from the broadband residential gateway 300. The dialed digits may then be transferred to the call manager 218 one at a time as they are entered. Alternatively, where the call set-up control process is shared between the broadband residential gateway 300 and the call manager 218, the broadband residential gateway 300 collects the dial digits and transfers these, together with the off-hook signal to the call manager 218. This transfer may be facilitated by combining this data into a single data packet.

4. On receiving the dialed digits, the call manager 218 will determine whether local number portability has been enabled. Where local number portability has been enable, the call manager 218 may issue a local number portability (LNP) query 511 to the IP local number portability database 122. The IP local number portability database 122 may then supply the call manager 218 with a routing number 512 if the dialed digits form a valid sequence. Where the dialed digits do not form a valid sequence, the call manager 218 will return an error indication to the broadband residential gateway 300. The error designation may include a tone and/or a more detailed error message for display on, for example, display 338.

5. Where the call sequence is valid, the call manager 218 may issue a first call proceeding message 513 to the broadband residential gateway 300 indicating that the number is valid and the call is proceeding (e.g., a valid on-hook condition).

6. Next, the call manager 218 typically determines whether adequate network resources are available to carry the call. In embodiments where the broadband residential gateway 300 is connected to a hybrid fiber-coaxial plant 112, the call manager 218 may send an open gate allocation request 514 to the cable modem transmission system 116. In this event, it is often desirable for the cable modem transmission system 116 to provide a gate allocation acknowledgement 515. A gate allocation acknowledgement may be utilized to verify that the necessary gate resources have been allocated.

7. The call manager 218 may send an open connection request 516 to the voice gateway (VG) 232 in order to provision the connection. Once the connection is provisioned, the VG 232 may provide an open connection acknowledgement 517 back to the call manager 218.

8. For off network connections, it is often necessary to enter a second phase of the connection process involving the appropriate link signaling to establish a call. For example, the call manager 218 may send an ISUP LAM (Initial Address) message 518 containing the directory number (DN) of the called party to the signaling gateway (SG) 234. This process is often utilized to allocate the appropriate voice trunk for communication. The call manager 218 may also send an alerting message 519 t the broadband residential gateway to produce an alerting signal, e.g., a ringing tone. The signaling gateway 234 may make the appropriate connections when the trunk has been allocated and acknowledge the request with an ISUP A call manager (Address Complete) message 520.

9. Once the called party has answered the call and connection is established, the signaling gateway 234 may send an ISUP ANM (Answered) message 521 to the call manager 218 indicating that the called party has answered.

10. The call manager 218 may then send a call start message 522 to the accounting gateway (AG) 240, indicating the start of the call. The AG 240 may use this information for billing purposes.

11. At this point, the link has been established and the conversation 523 can proceed over the communications path. Note that although signaling system 7 (SS7) signaling is used herein to illustrate the present invention and is a well known signaling protocol utilized in the art of telephony telecommunication, the instant invention is not limited to the use of signaling system 7 (SS7) signaling for call establishment of an off-network call; the use of signaling system 7 (SS7) signaling is merely illustrative. As such, other methods of signaling may be substituted for signaling system 7 (SS7).

11. When the called public switched telephone network user terminates the link, an on hook signal may be sent to the appropriate public switched telephone network switch, such as a 5ESS. The signaling network may then send a call termination message (not shown) to the signaling gateway 234 as notification of the call termination status.

12. The signaling gateway 234 may then generate a release 524 signal to the call manager 218.

13. Upon receipt of the release 524 signal, the call manager 218 may a) initiate the relinquishment of the provisioned network resources by issuing a close connection 525 message to the voice gateway (VG) 232 and a release complete 526 message to the signaling gateway 234, b) inform the accounting gateway that the call has been terminated, for billing purposes via, for example, sending a call end 527 message to the accounting gateway 240.

14. With reference to the close connection 525 message, the voice gateway may respond by issuing a report message 528 to the call manager 218 containing the current status of the call.

15. On receiving the call status report 528, the call manager 218 may issue a delete connection 529 message to the broadband residential gateway 300.

16. The broadband residential gateway 300 may then releases its resources and sends a status report 530 to the call manager 218. In addition to the report 530, the broadband residential gateway 300 may also send an on hook 531 status report to the call manager 218.

17. The call manager 218 may then inform the broadband residential gateway 300 to report the next off hook condition via message 532.

18. Where a cable modem transmission system is utilized, the call manager 218 may then issues a release gate 533 message to the cable modem transmission system 116 so that all the modem resources can be relinquished. Once the gate resources have been released, the cable modem transmission system 118 sends a release gate complete 534 message to the call manager 218. At this point, all resources pertaining to the call have been relinquished.

C. EXEMPLARY CALL FLOW OF AN ON-NETWORK CALL TO ANOTHER ON-NETWORK USER, UNDER ONE CALL MANAGER CONTROL

FIG. 6 illustrates an exemplary call flow of an on-network call to another on-network user, with the call being handled by a single call manager (CM) 218. In alternate embodiments, different portions of the call set-up sequence may be handled by more than one call manager 218 in the IP network 120. The exemplary “on-network” call processing sequence operates as follows:

-   -   1. Once the broadband residential gateway 300A detects and off         hook condition of, for example, a telephone, the broadband         residential gateway 300A may generate an off hook signal 607 to         the call manager (CM) 218. The off hook signal may act as a dial         tone request to the call manager 218.     -   2. The call manager 218 may then issue a dial tone message 608         to the requesting near-side broadband residential gateway 300A         in order for the broadband residential gateway 300A to generate         a dial tone.     -   3. The call manager 218 may then enter a state where it polls         and collects the dialed digits 609 from broadband residential         gateway 300A. The dialed digits are transferred to the call         manager 218 one at a time. In a similar fashion to the subject         matter discussed above, in embodiments where the call setup is         shared between the call manager 218 and the broadband         residential gateway 300A, the broadband residential gateway may         manage the call set-up and transfer both the off-hook signal and         the dialed digits to the call manager 218 within one or more.     -   4. On receiving the completed dialed digits, the call manager         218 may issue a local number portability query 610 to the IP         local number portability database 122. The IP local number         portability database 122 may then supply the call manager 218         with a routing number 611 if the dialed digits constitute a         valid sequence.     -   5. The call manager 218 may then ensure that adequate network         resources are available to accommodate the call.     -   6. Where adequate resources are available, the call manager 218         may issue a first setup message 612 to whatever mechanism         couples the far side broadband residential gateway 300, e.g.,         the cable modem transmission system 116B, to allocate         transmission resources on the far side.     -   7. A call proceeding message and a report on hook condition         message 613 may then be sent to the broadband residential         gateway 300A.     -   8. A gate allocation message 614 may then be sent from the call         manager 218 to the cable modem transmission system 116A, where         the broadband residential gateway 300A is coupled via a cable         modem transmission system. In this environment, a gate         allocation 614 message may be utilized to set up the relevant         modem resources.     -   9. Where a cable modem transmission system is utilized and         receives the setup message 612 from call manager 218, the cable         modem transmission system 116B may then send a connection         request 615 message to the far side broadband residential         gateway 300B.     -   10. Where a cable modem transmission system 116B is utilized,         the cable modem transmission system may then sends a setup         acknowledgement 616 to call manager 218. Once the resources are         allocated by the cable modem transmission system 116A, the cable         modem transmission system may then send a gate allocation         acknowledgement message 617 back to the call manager 218.     -   11. Once the call manager 218 receives the setup acknowledgement         616 along with the gate allocation acknowledgement message 617,         the far-side broadband residential gateway 300B may then send a         ringing message 618 to the far-side cable modem transmission         system 116B where this connectivity is utilized.     -   12. In these embodiments, the far-side cable modem transmission         system 116B may then issue an alerting message 619 to the call         manager 218.     -   13. The call manager 218 may then convey the alert via an         alerting message 620 to the broadband residential gateway 300A,         to produce a indicating signal such as a ringing signal         indicating that the call is going through.     -   14. The cable modem transmission system 116B may then issue a         connect message 622 to the call manager 218 in response to the         far-side broadband residential gateway 300B sending an off hook         message 621 to the far-side cable modem transmission system         116B. At this point, the end-to-end communication path is         established and conversation 623 can be facilitated.     -   15. Assuming that the calling party hangs up first, the         broadband residential gateway 300A may initiate an on hook         sequence 624 message which may be communicated to the near-side         cable modem transmission system 116A.     -   16. The cable modem transmission system 116A may then issue a         disconnect message 625 to the call manager (CM) 218. The call         manager 218 may then issue a first delete connection request 626         to the near-side broadband residential gateway 300A and then a         second delete connection request 627 to the far-side broadband         residential gateway 300B.     -   17. The near-side broadband residential gateway 300A may respond         to the call manager 218 with a report message 628 containing the         connection status, as well as an on hook message 630 to verify         that the calling party at near-side broadband residential         gateway 300A has terminated the call.     -   18. The far-side broadband residential gateway 300B may respond         to the call manager 218 with a report message 629 containing the         connection status, as well as an on hook message 631 indicating         that the called party connection has now been terminated.     -   19. At this point, the call manager 218 may issue release gate         messages 634 and 635 to the near-side cable modem transmission         system 218 and far side cable modem transmission system 116B,         respectively, so as to release the modems associated with the         call. Once all the resources have releases, the cable modem         transmission system 116A and the cable modem transmission system         116B may issue gate release complete messages 636 and 637         respectively to the call manager 218.     -   20. For simplicity, the accounting processing is not shown.         However, the process used in FIG. 5 may be utilized as the         billing procedure for on-net calls. Such a process might         constitute sending a call start message from the call manager         218 to an accounting gateway (AG) 240 after the connect message         622 is sent from the far-side cable modem transmission system         116B to call manager 218. The call start message would trigger         the start of the billing procedure. A corresponding call end         message would then be sent from the call manager 218 to the AG         240 after the near-side cable modem transmission system 116A         sends a the disconnect message 625 to the call manager 218. This         call end message would trigger the ending of the billing         procedure for that call.         Although the IP voice packets for these calls are typically         routed over the IP network 120, the system may, where         appropriate, route IP voice packets over the Internet 180.

II. BROADBAND CABLE TELEPHONY NETWORK ARCHITECTURE

The present invention provides a system and method for voice, video and data communication in an Internet Protocol (IP) based network. The invention may be coupled to the infrastructure of the Public Switched Telephone Network (PSTN) to control telephone calls in SS7 type networks and provides typical PSTN features in a voice over IP network. In particular, the present invention supports large call volumes, allows accommodation of a wide range of service platforms, provides flexibility to support current and future calling features, and may be arranged to provide high quality voice, video and data transmission.

FIG. 7 is a schematic representation of one embodiment of a Customer Premises Apparatus 702 coupled to an Internet Protocol Capable-based/Hybrid Fiber Coaxial (HFC) network 112 in accordance with the present invention. The CPE may include a Broadband Residential Gateway (BRG) 300 and other CPE devices such as television (TV) 106, a personal computer (PC) 108, and the plain old telephone system (POTS) phone(s) 110. The BRG 300 is generally a CPE component of the system that interfaces with the Internet Protocol Capable/Hybrid Fiber Coax (HFC) network 112 and provides the user with both high-speed data (Ethernet) and telephony access in addition to HDTV, Digital TV and current CATV services.

The BRG 300 may be an interface unit between the indoor CPE devices and the outdoor HFC network 112 and typically supports the following functions: a high-speed cable modem to connect to a PC 108 for data purposes, a Set Top Box (STB) 114 to connect to a TV 106 for video purposes, and multiple POTS telephone ports 110 for telephony purposes.

FIG. 8 shows a schematic of one embodiment of a HFC distribution network 112 for connecting a Head-end Hub (HEH) 115 with the CPE network 102. In most HFC network systems, at least two fibers link each laser module to the HEH 115, one forming a Primary Hub (PH) 808 for the upstream traffic and one forming a Primary Hub 808 for the downstream traffic. Typically, the Primary Hubs 808 form a Primary Ring 802 wherein the Primary Hubs 808 are then joined at another Primary Hub that is coupled to a Secondary Ring 804. The Secondary Ring 804 typically includes at least Secondary Hubs 810 that multiplex signals to a plurality of Fiber Nodes 812. In the downstream direction, the Fiber Nodes 812 convert the optical signals to electrical signals and send the electric signals out on the coaxial (tree and branch) network 806 that sends the electrical signals to the CPE devices. In the upstream direction, the Fiber Nodes 812 convert the electrical signals received from the coaxial (tree and branch) network 806 to optical signals.

The HFC network 112 is typically a scaleable architecture that, in major metropolitan systems, may be implemented as a dual star bus. However, all the elements of the network may be selected to be deployed in all regions in a non-uniform manner. For example, the deployment of Secondary Hubs or route diverse Secondary Rings might depend upon factors such as the market penetration or the geographical distribution of subscribers.

In a typical hub, HFC Systems with fewer than 100,000 subscribers may not have a primary ring or metropolitan/regional network; smaller systems may not even employ the secondary hub portion of the network. The Secondary (fiber) Ring 804 typically supports two diversely routed paths between the Primary Hub and any of the subtending Secondary Hubs, except in remote and sparsely populated areas.

FIG. 9 shows a one embodiment of a spectrum use diagram for the coaxial portion of an HFC network in accordance with the present invention. The downstream frequency block (above 50 MHz) 902 may be divided into 6 MHz channels, most of which are used to support a CATV company's video service. One or more of the 6 MHz channels is designated to support downstream data transmission. Digital data may be modulated onto the 6 MHz channel using either 64 QAM (Quadrature Amplitude Modulation) or 256 QAM. With 64 QAM, each 6 MHz channel can typically support up to 27 Mbps of data. With 256 QAM, each 6 MHz channel can support up to 38 Mbps of data.

The upstream frequency block 904 (between 4 and 42 MHz) illustrated in FIG. 8 may be divided into channels of varying width (between 0.20 to 3.20 MHz). Frequency ranges and channel widths are chosen based on known typical ingress patterns (DOCSIS 1.0 or later release). Assuming a typical cable plant, upstream data channels of 1.6 MHZ may be selected in the unused frequency ranges of the upstream frequency block. Depending on specific plant characteristics, either QPSK or QAM16 may typically be selected as the upstream modulation technique. With a 1.6 MHz channel 1280 ksym/sec can be supported. Hence, QPSK can theoretically support up to 2.56 Mbps and QAM16 can theoretically support up to 5.12 Mbps.

The current invention and architecture utilizes a typical Head-end Hub (HEH) 115 that acts as the interconnection point to gather and transform external services (e.g., off air and satellite video, PSTN voice, and Internet data) to bring them onto the HFC network 112. FIG. 10 is a schematic representation of one embodiment of an HEH architecture in accordance with the present invention. In this architecture, video signals are inserted into the Laser Module (LM) 1002 for up/downstream transmission. An Edge Router (ER) 118 typically provides traffic routing to a high speed packet network 120 n (i.e., SONET) for data transmission.

Generally, an ER 118 may be utilized between the cable modem bank 1004 and the HPN to protect the network against user mistakes and intrusions (hackers), to provide Quality of Service (QoS) policing with Service Level Agreements (SLAs) (e.g., IP precedence bits)—differentiating voice and data traffics, to enforce security policy of traffic flows via access lists (e.g. non-telephony CPE devices are unable to access the voice portion of the network), and to limit broadcasts (avoid broadcast noise).

The Edge Router ER 118 generally provides fast switching capability as well as bandwidth aggregation capability. Multiple port adapters may be equipped on the ER 118 to provide a load-shared, dual-redundant connection to the HPN backbone. Failure of either a link or an IP backbone node attached to a link will not result in any service degradation.

The interface between the cable modem bank 1004 and the ER 118 is typically an open interface, thereby accommodating many implementations. The HFC network interfaces are typically provided by multiple plug-in modem cards that reside in the cable modem bank 1004. Each cable modem bank 1004 may be selected to have the following functions:

1) Cable Media Access Control (MAC) unit: The cable MAC frames and encrypts the downstream signal for RF transmission and passes the signal to the downstream physical layer (PHY). It reverses the signal framing and encryption on the upstream signal from the upstream PHY.

2) Downstream PHY unit: The downstream PHY generates a modulated, intermediate frequency (IF) output signal at a frequency of 44 MHz and passes the IF signal to an external IF to an RF up-converter installed in the downstream path.

3) Upstream PHY unit: The upstream PHY receives the modulated, upstream signal at a frequency of 5 MHz to 42 MHz and passes the signal to the cable MAC to remove the framing and encryption formats.

4) Spectrum management: The spectrum management function continuously monitors the noise in unused upstream channels. If the signal-to-noise ratio reaches an unacceptable level on a particular channel, the spectrum management module will automatically assign a new upstream channel to the cable modem using that channel (frequency agility). Generally, this reassignment takes no more than 20 ms, and the active call will not be dropped.

The ER 118 is generally equipped with a 100 Base-T interface built into the I/O board with support for both MII and RJ45 physical interface. Each cable modem card in the cable modem bank 1004 may provide at least one downstream cable F-connector port and multiple upstream cable F-connector ports. Each cable modem bank 1004 typically contains multiple slots for multiple modem cards. The aggregate bandwidth between the cable modem bank 1004 and the ER 118 provides cost and footprint saving.

The IP Network 120 may provide connectivity for the HEH 115 and its customers in the CPE 102 to the Internet 180 utilizing the IP Central Station 200 and connectivity to other external networks such as PSTN and SS7 226 for end-to-end voice over IP applications.

FIG. 11 is a schematic representation of one embodiment of a packet over SONET High-speed Packet Network in accordance with the present invention. The physical topology consists of Ultra High-speed Routers (UHR) 121 feeding into SONET Add/Drop Mux (ADM) 1102 interconnected over a dual fiber ring 1104. Logically, the UHRs 121 may be connected via a full-mesh of point-to-point connections. The speed of the SONET rings and the Packet Over SONET (POS) interfaces depends on the number of subscribers in the region served by the network.

The main function of UHR 121 is typically to run routing protocols and build routing tables. Each UHR 121 typically has multiple high-speed line cards that support IP switching capacities up to 40 Gbps or higher and data rates up to OC-48 or higher speeds. Network interfaces are typically provided on a variety of plug-in line cards: Gigabit Ethernet Line card—Gigabit Ethernet is provided on a Gigabit Ethernet Interface line card that plugs into the UHR; using OC-3, OC-12, OC-48 or OC-192 with Packet Over SONET (POS)—A variety of SONET interface cards may be supported by the UHR as well. The OC-12c POS line card, for example, provides the UHR 622-Mbps single-mode or multi-mode SONET/SDH connection.

In this embodiment, the SONET Add/Drop Multiplexer (ADM) 1102 is typically a Synchronous Optical Network (SONET) digital multiplexer that is capable of accepting a wide range of inputs and performs the necessary conversion to the SONET signaling rate. An ADM 1102 can accept multiple inputs from its lower-speed ports such as DS1, DS3, etc. and multiplex them to the specified higher output rate such as OC-12, OC-48, etc. Cross-connect capability is provided in the ADM 1102 by using time slot assignments. Data may be added into or dropped from the high-speed carrier facility without the need to demultiplex the signal. The ADM 1102 may use redundant hardware and optical lines for automatic protection switching when a failure occurs. If a cable cut occurs in the SONET ring, the ADM 1102 typically will use its internal loopback circuits to re-route the data without interruption to the service.

The Call Manager (CM) 218 typically may be the call control center for supporting the Voice over IP (VoIP) application. In general, the main functions performed by the Call Manager 218 may be: trunk and line information maintenance, calling state maintenance during the duration of a call, and user service features execution as appropriate. In one embodiment, signaling information is communicated between the Call Manager 218 and the PSTN using SS7 ISUP messages. Call signaling within the IP network may use SGCP, MGCP or another open interface from the Call Manager to other network elements. In one embodiment, the Call Manager 218 may use a half call model structure, where each half-call model is a finite state machine that captures the call progress states of an IP Telephony call.

FIG. 12 is a schematic representation of one embodiment of the connectivity among the Call Manager (CM) 218, the Voice Gateways (VGs) 232, Accounting Gateway (AG) 240, Element Management Gateway (EMG) 238 and the PSTN network 160 in accordance with the present invention. In one embodiment, a database of customer information is accessed that represents the features subscribed to and the specific dialing plan, and the individual line triggers and executes the call logic based upon the individual line triggers. The Call Manager 218 may have interfaces to the SS7 Gateway 234, the Accounting Gateway 240, the Element Management Gateway (EMG) 238 and Voice Gateway (VG) 232 using IP protocol. Generally, the Call Manager 218 uses the following signaling messages to support VoIP application: ISUP messages over CORBA interface to/from Signaling Gateway, SGCP/MGCP control messages to/from Announcement Server, Call event records in modified Radius format to the Accounting Gateway 240, SGCP/MGCP control messages to/from VG and the BRGs, SNMP messages to/from the Element Management Gateway 238, and Database requests to/from the provisioning Operations Support Systems (OSSs) 195.

The Call Manager 218 may provide the calling architecture for the calls, maintain the call states for each call and respond to the events represented by SGCP/MGCP messages or ISUP messages that occur during the processing of a call. These events may include state changes, feature triggers, changes in the status of lines and trunks and error conditions.

The Call Manager 218 may interact with endpoints on a Voice Gateway 232 or a BRG 300. An endpoint is a single trunk circuit or a single telephone port located on a VG 232 or a BRG 300 respectively. The number of clusters that a particular CM 218 can support depends on the traffic load requirements for the endpoints (residential or trunking) as well as the processing power of the CM machine. The Call Manager 218 typically provides storage for subscriber and network configuration, may contain the cache server for faster access to the data, may include a routing engine for selecting least cost routing and may include a service broker which provides the data and logic for specific services.

The Call Manager 218 may use databases that are created/modified and/or deleted by the provisioning OSSs. Such databases typically store the following information: Resources database: provides an identification of what resources are connected to the network and their current state; the Trunk/Gateway database: indicates which gateway serves what circuits in a trunk; the customer database: needed to authorize a call, identify what services a line supports and whether a telephone number is on or off net; the numbering plan/least cost routing database: provides routing information, enables the SCC to choose correct trunk, as a function of the call number; and the Local Number Portability (LNP) database: indicates the NPA/NXX prefixes for which the number portability service is open, and the address of the SCP towards which requests for translating these numbers should be routed. The triggering information, i.e. the list of prefixes, will have to be present in the database. An external SCP in the SS7 network will provide the actual LNP database.

Physical interfaces are provided through plug-in line card interface modules and typically include the following: Fast Ethernet—The Fast Ethernet interface module supports multiple Fast Ethernet ports over Category 5 UTP copper cable with RJ-45 connectors; and Gigabit Ethernet—The Gigabit Ethernet interface module supports multiple Gigabit Ethernet ports.

The present invention may utilize the “Simple Gateway Control Protocol” (SGCP) or a later protocol such as, for example, MGCP or H.GCP. Where MGCP or H.GCP is utilized, MGCP or H.GCP may use text encoding to control the allocation of circuits in the Voice Gateways. The protocol is carried over UDP, and is designed to allow the control of a connection to move from one Call Manager platform to another, allowing the network to support very large configurations. UDP shortens delays, provides scalability and allows for more efficient failover procedures. The MGCP or H.GCP Notification Request and Notify command maintain synchronization. MGCP or H.GCP is also capable of carrying basic signaling events, such as hook actions and dialed numbers. It is generally used, alone, to carry signaling between the Call Manager and the BRGs and other endpoints. The MGCP or H.GCP typically implements gateway control as a set of transactions. The transactions are composed of a request and a mandatory response. In general, there are five types of requests: CreateConnection; ModifyConnection; DeleteConnection; NotificationRequest; and Notify.MGCP or H.GCP messages are transmitted over UDP. Requests are sent to one of the IP addresses defined in the DNS for the specified endpoint. The responses are sent back to the source address (MGCP or H.GCP) of the requests. MGCP or H.GCP messages, being carried over UDP, may be subject to losses. In the absence of a timely response, requests are repeated.

With respect to the Gateway (GW) Architecture, the Gateways typically support, among others, the following group of functions: Call Processing; SS7 Connectivity; Billing Support; OAM&P Support; Connection to PSTN; Control CoS/QoS parameters; and Enhanced services.

A trunk side Voice Gateway (VG) 232 is a highly reliable box that converts IP based voice packets into standard PSTN voice traffic. For MF trunks, signaling between the Call Manager and the Voice Gateways may be done via MGCP or H.GCP. Voice Gateways may be configured as MF or ISUP gateways on a per-T1 basis. MF trunks will be compatible with Feature Group D (FGD), Operator Service (OS) Signaling protocol and Termination Protocol (TP).

The bearer channel connection with the ILEC and IXCs may be accomplished via T1 carrier connections. Generally, either ISUP or MF, FGD, OS signaling trunks may be used to interconnect to the service bureau (possibly the ILEC) providing operator services, directory services and positions for 311, 611 and 711 services. E911 calls are routed to an E911 tandem switch 1202 that has the appropriate databases and interfaces with the Public Safety Answering Position (PSAP) 1204.

As shown in FIG. 13, the VGs 232 may be router-based with Voice Feature Card and DSP Module cards to do the voice processing. In one embodiment, key features that a VG 232 may provide are: a Host processor 1302 and LAN/WAN ports; Ethernet ports and T1 or E1 telephony interface cards 1308; Voice Feature Card 1304 with DSP Modules 1306 providing voice compression transcoding (G.711 and G.729); Carrier-quality echo cancellation: 8 ms-32 ms tail length; a de-jitter buffer which adapts to delay variations in the network in order to minimize the delay; packet loss concealment that generates concealment frames for lost packets using information from previously received data; and tone detection and generation. The tone detection and generation function typically detects Multi-Frequency (MF) tones and generates MF and call processing tones (e.g. dial tone, call-waiting tone etc.).

Typically, the VG 232 supports T1/E1 interfaces with internal CSUs, ISUP, MF and Centralized Attendant Services (CAS) trunks are supported with a configuration done on a per T1 basis. For MF/CAS trunks, CAS signaling (ABCD signaling bits and MF tones) is converted to/from SGCP/MGCP/H.GCP signal requests and events by the Voice Gateway 232. This includes: MF tones converted to/from digit strings inside either an SGCP/GCP/H.GCP Notify or Notification Request (or combined with a Connection or Modify Connection Request); Off-hook and on-hook indications converted to/from events inside either an SGCP/MGC/H.GCP Notify or Notification Request (or combined with a Connection or Modify Connection Request); and Lower level signaling and timing done within the Voice Gateway itself (e.g. wink-start) rather than controlling via SGCP/MGCP/H.GCP.

An ethernet interface on an RJ45 connector may be used to connect the VG 232 into the SCC high speed router. SGCP/MGCP/H.GCP is typically used as the interface between the Voice Gateway 232 and the Call Manager 218 for call control, signaling and media stream purposes. SGCP/MGCP/H.GCP may be used to set up RTP connections (IP addresses, UDP ports, codec choice etc.). Audio streams are then passed directly between endpoints via RTP over UDP. SGCP/MGCP/H.GCP may be used to send requests to the Voice Gateway 232 to make or modify connections in order to set up RTP media streams and to request continuity tests and results.

In one preferred embodiment, a SS7 Signaling Gateway (SG) supports SS7 signaling TCAP message to SGCP/MGCP/H.GCP message exchange. ISUP and TCAP signaling is terminated on SS7 Signaling Gateways, which looks like an SSP to the SS7 network. The Call Manager 218 uses and API with SS7 to send and receive ISUP and TCAP messages. Full class 5 SS7 functionality may be provided, including the ability to provide all of the information necessary for billing as defined in GR-246-Core. The SS7 Gateway is arranged to perform for: SS7 message handling (message discrimination, message distribution, and message routing); Signaling Link Management (e.g., link activation, deactivation); Signaling Route Management (managing Point Code route status based on route received management messages such as Transfer Prohibited, Transfer Allowed, Transfer Restricted, etc.); and Signaling Traffic Management (diversion of traffic based on unavailability, availability, restriction of signaling link, route, and point code.) The SS7 architecture supports the necessary redundancy component scheme for the system reliability and availability during scheduled maintenance and/or software/hardware upgrades. The SS7 Gateway handles all of the lower level SS7 processing and is connected to the Call Manager via an open interface (i.e., SCP/MGCP/H.GCP, CORBA). For the ISUP or TCAP application level data received from the Call Manager 218 via this open interface, the SS7 Gateway software adds the MTP layer information to create a complete SS7 message to be sent to the STP pair in the external SS7 network via the A-linksets. Conversely, the SS7 Gateway software strips the ISUP or TCAP application layer data from the SS7 messages received from the STP pair and sends it to the Call Manager using the open interface.

The Accounting Gateway receives messages representing events from the Call Manager. Up to two messages are received for each call, the first when the call is established, and second when the call terminates. In the case of unsuccessful calls, only the failure message will be logged. The messages provide details about the calling and called parties, the tiring of the call set-up, the duration, the type of calling feature and the quality of the call. Accounting gateways (AG) are duplicated, with each gateway having dual-mirrored disks. Each gateway is able to handle up to 3-days worth of accounting records. If an AG fails, Call Managers will begin revert to the backup AG.

The Standard Automatic Message Accounting (AMA) format is typically used by circuit-switching systems, packet-switching systems, and other network elements to provide billing usage measurements data. These data are needed either to permit charging the customer for use of network services or to permit charging other carriers (including IECs and other LECs) for assistance in placing call connections. The Accounting Gateway converts this information into AMA records and sends these records to the external Billing Systems using FTP. Time-stamp accuracy is based on the accuracy of the Call Manager clock that derived from the TOD. To create appropriate AMA records, the event information produced by the Call Manager must have appropriate information for the telephone service required. This includes and is not limited to: phone number of the calling party (customer); phone number of the called party (customer); time of call; duration of the phone call; and use of any discretionary features. In terms of billing for On-Net vs. Off-Net calls, different AMA structures are generated between On-Net (defined as within a network service provider network) and Off-Net (defined as outside of service provider network—e.g. PSTN) calls.

The purpose of the Element Management Gateway (EMG) is to provide at least the following system management functionality: Status and performance monitoring for the operation center to gauge the ongoing operation of applications; Provide extensive information for operations center who may not have been involved in the development of the applications but on whose hands the ongoing maintenance of the application falls; Customizable operations interface to allow the Work Center to view only the information required reducing the time spent filtering information; Centralize distributed application configurations that may be spread across many objects on many machines; Proactive management capabilities to remove the need for constant operator intervention making the day-to-day operations more efficient; and Intelligent display of status information to separate critical issues from low-priority problems allowing the operation center to assign resources to the right problems at the right time.

The Operation, Administration, Maintenance and Provisioning (OAM&P) connectivity may be provided by a Secured Management Data Network (SMD Net). FIG. 14 shows a schematic representation for one embodiment of an architecture for a SMD Net interconnect system in accordance with the present invention. An Element Management Gateway (EMG) 238 is coupled to an SMD Net 1402 by a T1 or higher data rate line. The SMD Net 1402 is coupled to Network Operation Centers 1408 in an OAM&P 195, a Network Server Platform (NSP) 1408, and a plurality of Work Centers (Field Service Area) 1406.

FIG. 15 is a block diagram of a preferred embodiment of a Broadband Residential Gateway BRG in accordance with the present invention. All elements of the BRG are coupled to the Power Supply Unit 1520; thus, further descriptions of the couplings to the Power Supply Unit 1520 will not be described below. The BRG may include a transceiver 1502 with RF to packet logic/packet logic to RF coupled to an HFC cable interface, typically using an F connector cable connection. The transceiver 1502 typically receives an RF frequency input from an input port and forwards the input to digital signal processing software, firmware and hardware modules for IP packet processing. Thus, the transceiver 1502 converts RF to IP packets, essentially serving as a modem and translator. A Universal Register Logic Unit 1504 is typically coupled to the transceiver to provide an elastic register for queuing and tunneling IP packets required for IP services. In a preferred embodiment, the telephony ports 1532, data port 1534, and TV port 1536 are coupled to the smart buffer logic 1524 using a high speed bus (HSB); the Distributed Processing Architecture Platform (DPAP) 1506 is coupled to the Smart Buffer Logic 1524, the Flash Memory 1522, and the Universal Register Logic 1504 using a HSB; the Flash Memory 1522 is coupled to the Display Driver Touch Screen Logic 1538 using a HSB; and the Universal Register Logic 1504 is coupled to the transceiver 1502 using a HSB. Logical signaling connections couple the telephony ports 1532 to the telephony services and processing electronics and firmware 1526, the data port 1534 to the high speed data services and processing electronics and firmware 1528, the TV port 1536 to the CATV/HDTV services and processing electronics and firmware 1530, the smart buffer logic to the services and processing electronics and firmware 1526, 1528, 1530 and to the Flash Memory 1522, the DPAP 1506 to the services and processing electronics and firmware 1526, 1528, 1530, to the transceiver 1502 and to the transceiver 1502, the Flash Memory 1522 to the Smart Buffer Logic 1524, and the Display Driver Touch Screen Logic 1538 to the Universal Register Logic 1504.

Though processing may be accomplished by a single processor, in a preferred embodiment, as shown in FIG. 15, processing is distributed across a distributed processing platform 1506, taking place in a plurality of processors P1-P6 1508-1518, each having a dedicated function and being designed to provide predetermined services or applications, and being coupled to the other processors via a Universal Service Bus (USB). A first processor P1 1508 is dedicated to telephony; a second processor P2 1510 is dedicated to data; a third processor P3 1512 is dedicated to video; a fourth processor P4 1514 is an auxiliary processor; a fifth processor P5 1516 is utilized for interface (e.g., text to voice and vise versa) input/output processing; and a sixth processor OAMP P6 1518 is utilized for Operation, Maintenance and Provisioning processing. The processing platform 1506 is coupled to the Universal Register Logic Unit 1504, the Flash Memory 1522, a Smart Buffer Logic unit 1524 and to a plurality of system service units 1526, 1528, 1530. The system service units include logic, electronics, firmware and circuitry for telephony services 1526, high speed data services 1528 and CATV/HDTV (Cable Television/High Definition Television) 1530 in accordance with standard industry practices such as DOCSIS 1.0 or higher, etc.

The Flash Memory 1522 is coupled to the distributed processing platform 1506 and serves as a Random Access Memory for processing functions. In a preferred embodiment, the Flash Memory 1522 includes field-upgradeable slots for permitting addition of additional memory that may be required for highly specialized computing applications requested by users, such as multi-party conferences, call waiting for multiple parties, etc.

The Smart Buffer Logic unit SBL 1524 is coupled to the telephony ports 1532, data ports 1534, TV ports 1536, and the distributed processing platform 1506. The SBL unit 1524 has a main function of buffering the IP packets for delivery over the HFC network. In addition, the SBL unit 1524 may include selectable switching and routing algorithms based on services and applications associated with each port.

The telephony ports 1532 have circuitry, hardware, logic and firmware for interfacing with the Plain Old Telephone networks (POTs) as is known in the art. Also the telephony ports 1532 typically include user interface logic, voice processing logic, voice activity detector logic, voice codecs, and DTMF (dual tone multi-frequency) tone sensing logic. In a preferred embodiment, RJ11 interfaces to a maximum of 4 lines are provided for users to connect existing telephone units. Echo cancellation and automatic gain control may also be utilized in the telephony port 1532.

The data port 1534 interfaces high speed data service to users in accordance with Ethernet 802.3, using an RJ45 interface to the Ethernet Card in a personal computer. The data port 1534 typically also includes circuitry, hardware, firmware and logic interfaces, essentially characterized as a cable modem logic unit as is known in the art.

The TV port 1536 is an interface for HDTV and/or CATV services to users' television sets

Although the invention has been defined using the appended claims, these claims are exemplary and limiting to the extent that the invention is meant to include one or more elements from the apparatus and methods described herein and in the applications incorporated by reference in any combination or subcombination. Accordingly, there are any number of alternative combinations for defining the invention, which incorporate one or more elements from the specification (including the drawings, claims, and applications incorporated by reference) in any combinations or subcombinations.

The following copending U.S. Patent applications, originally filed the same day as the present application, are hereby incorporated by reference:

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No. 09/476,494, entitled “Broadband     Service Access,” invented by Kung et al. -   23. U.S. patent application Ser. No. 09/475,798, entitled “Method     for Providing Broadband Public IP Services,” invented by Kung et al. -   24. U.S. patent application Ser. No. 09/475,797, entitled “Method     For Billing IP Broadband Subscribers,” invented by Kung et al. -   25. U.S. patent application Ser. No. 09/475,165, entitled “BRG With     PBX Capabilities,” invented by Kung et al. -   26. U.S. patent application Ser. No. 09/475,783, entitled “Enhanced     IP Subscriber Alerting,” invented by Kung et al. -   27. U.S. patent application Ser. No. 09/475,782, entitled “Chase Me     System,” invented by Kung et al. -   28. U.S. patent application Ser. No. 09/475,673, entitled “Call Hold     With Reminder and Information Push,” invented by Kung et al. -   29. U.S. patent application Ser. No. 09/475,293, entitled “Activity     Log For Improved Call Efficiency,” invented by Kung et al. -   30. 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1. A two-way communication system for providing universal multimedia applications including voice calls over Internet Protocol, comprising at least: a Broadband Residential Gateway coupled to a plurality of customer premises equipment and to a Hybrid Fiber Coaxial network, a Head End Hub comprising: a Cable Modem Bank coupled to an Edge Router and to a Head End, the Edge Router, coupled to the Cable Modem Bank and to a High Speed Packet Network, wherein the Head End Hub is coupled to the Hybrid Fiber Coaxial network and to a High-Speed Packet Network, the High Speed Packet Network coupled to the Head End Hub and to an Internet Protocol Central Office, and the Internet Protocol Central Office, coupled to the High Speed Packet Network and to an external network.
 2. The two-way communication system of claim 1 wherein the plurality of customer premises equipment includes at least one of: a television, a telephone and a personal computer.
 3. The two-way communication system of claim 1 wherein the external network is a public switched telephony network with a Signaling System Seven and an Operation, Administration, Maintenance and Provisioning system.
 4. The two-way communication system of claim 3 wherein the public switched telephony network includes a billing system.
 5. The two-way communication system of claim 1 wherein the High Speed Packet Network is coupled to an Internet Protocol Local Number Portability database that is coupled to a plurality of Ultra Highspeed Routers.
 6. The two-way communication system of claim 5 wherein the High Speed Packet Network is coupled to a Local Service Management System.
 7. A two-way communication system for providing voice calls using Internet Protocol, comprising at least: an Internet Protocol Central Station, coupled to the a public switched telephony network, Internet and to a plurality of Customer Premises Equipment CPE via at least one High-Speed Packet Network coupled to a Hybrid Fiber Coaxial Distribution Network, the High-Speed Packet Network having a plurality of Ultra High-speed Routers coupled to the Hybrid Fiber Coaxial Distribution Network, and the Hybrid Fiber Coaxial Distribution Network being coupled to a Broadband Residential Gateway of the CPE that interconnects a plurality of Customer Premises Equipment, wherein voice calls are transmitted over the system in packets formatted in accordance with Internet Protocol.
 8. The two-way communication system of claim 7 wherein the plurality of customer premises equipment includes at least one of: a television, a telephone and a personal computer.
 9. The two-way communication system of claim 7 wherein the public switched telephony network utilizes a Signaling System Seven and an Operation, Administration, Maintenance and Provisioning system.
 10. The two-way communication system of claim 7 wherein the public switched telephony network further includes a billing system.
 11. A method for providing a two-way communication system for a voice call formatted using Internet Protocol, comprising the steps of: using an Internet Protocol Central Station, coupled to the a public switched telephony network, Internet and to a plurality of Customer Premises Equipment CPE via at least one High-Speed Packet Network coupled to a Hybrid Fiber Coaxial Distribution Network, to encode a voice call to form IP encoded voice packets in accordance with the Internet Protocol and transmit said IP encoded voice packets on the High-Speed Packet Network using an Ultra High-speed Router coupled to the Hybrid Fiber Coaxial Distribution Network, wherein the Hybrid Fiber Coaxial Distribution Network is coupled to a Broadband Residential Gateway BRG of the CPE that interconnects a plurality of Customer Premises Equipment, and the BRG decodes the IP encoded voice packets to form a voice call and sends the voice call to a telephone.
 12. The method of claim 11 wherein the plurality of customer premises equipment includes at least one of: a television, a telephone and a personal computer.
 13. The method of claim 11 wherein the public switched telephony network includes a Signaling System Seven and an Operation, Administration, Maintenance and Provisioning system.
 14. The method of claim 11 wherein the public switched telephony network further includes a billing system.
 15. A two-way communication system for providing at least one of: voice, video, data and multimedia over Internet Protocol, comprising at least: a Broadband Residential Gateway coupled to a plurality of customer premises equipment and to an Internet Protocol Capable Network, a Head End Hub comprising: a Cable Modem Bank coupled to an Edge Router and to a Head End, the Edge Router, coupled to the Cable Modem Bank and to an Internet Protocol Network wherein the Head End Hub is coupled to the Internet Protocol Capable Network and to the Internet Protocol/High Speed Packet Network, the Internet Protocol/High Speed Packet Network coupled to the Head End Hub and to an Internet Protocol Central Office, and the Internet Protocol Central Office, coupled to the Internet Protocol/High Speed Packet Network and, where selected, to an external network.
 16. The two-way communication system of claim 15 wherein the plurality of customer premises equipment includes at least one of: a television, a telephone and a personal computer. 